JP2018191730A - Game machine - Google Patents

Abstract

To provide a game machine capable of removing monotonousness of performance image display.SOLUTION: In a pachinko game machine, the number of shot balls by a launcher within a prescribed time from start of a normal game state, and a fluctuation frequency of an identification pattern by start winning are stored, and a fluctuation frequency in the unit number of shot balls is determined, and ending display after finish of a jackpot game state displayed on a liquid crystal display device 50 is changed, according to the result, to thereby suggest to a player whether a pachinko game machine just playing a game has a tendency of getting start winning or not, through the ending display.SELECTED DRAWING: Figure 53

Description

  The present invention relates to a gaming machine using a gaming ball such as a pachinko machine.

In a conventional pachinko machine, when a game ball that rolls and flows into a starting prize opening provided on the game board is entered, a winning lottery is performed to shift to a game state advantageous to the player, When a plurality of symbols displayed on a display means such as a display device fluctuate and a winning lottery is won, an advantageous gaming state (so-called jackpot gaming state) triggered by a plurality of symbols stopping in a predetermined combination Migrate to
If a game ball enters the start winning opening while a plurality of symbols are changing on the display means, a winning lottery is performed, while the holding state is maintained until the plurality of symbols changing are stopped. Then, after the fluctuating symbols are stopped, the plurality of symbols are newly fluctuated and stopped based on the winning lottery already performed. The maximum number in the hold state is 4.

  On the other hand, in accordance with the lottery result, the display means displays an effect image or the like in accordance with the change or stop of the symbol, thereby enhancing the expectation of shifting to an advantageous gaming state.

  In Patent Document 1, the variation is maintained until the number of changes in the symbol after the end of the special game reaches the number of final variations, and the production determination means has a plurality of productions in which the correspondence relationship between the fluctuation pattern and the production pattern is defined. It describes that an effect pattern to be executed is selected with reference to one of the pattern tables.

Japanese Patent Laying-Open No. 2015-51323

  However, the selected effect pattern does not include elements other than the effect pattern according to the gaming state and the lottery result, and the effect to be executed tends to seem monotonous to the player.

  An object of this invention is to provide the gaming machine which solves the above-mentioned problem.

  In order to achieve the above object, the present invention has the following configuration.

(1) There is a game area (game area 41) where the game ball rolls and flows down, and a start winning opening (first start port 414a, second start port 414b) in which the game ball can enter the game area. A game board (game board 40) provided with
Launching means (launching device 20) for launching a game ball into the game area by the player's operation;
Lottery means (main CPU 101, processes in steps S34 and S43 in FIG. 8) for performing a lottery for shifting to a gaming state advantageous to the player, with the winning at the start winning opening,
A symbol display means (liquid crystal display device 50) for performing variable display and stop display of a plurality of symbols (three identification symbols 52);
In response to the game ball entering the start winning opening, a plurality of symbols are variably displayed, and the plurality of symbols variably displayed according to the lottery result of the lottery means are stopped and displayed in a predetermined combination. Symbol display control means (sub CPU 201, processing in steps S234 and S235 in FIG. 18),
Effect image display means (liquid crystal display device 50) for effect image display;
Effect image display data storage means (image data ROM 211) for storing a plurality of types of effect image display data;
Effect image display control means (sub CPU 201, process of step S224 in FIG. 18) for controlling the effect image display means in accordance with the lottery result by the lottery means;
Firing ball number storage means (work RAM 203 or main RAM 103) for storing the number of game balls fired by the launching means;
Initializing means (sub-CPU 201 (processing in step S1244 in FIG. 48)) or main for initializing the number of game balls stored in the number-of-fired-ball storage means and the number of times of symbol change display stored in the number-of-changes storage means CPU 101), and
The effect image display control means is initialized by the initialization means, and then the number of game balls stored in the number-of-fired-ball storage means, and the number of symbol fluctuation displays stored in the fluctuation number storage means, The effect image display control using any effect image display data among the plurality of effect image display data stored in the effect image display data storage means (sub CPU 201, step S1241 in FIG. 48). A gaming machine characterized by performing processing.

  According to (1), the effect image is not displayed according to the lottery result of the lottery means, but the number of game balls fired after being initialized by the initializing means and the number of times the symbols are changed are displayed. Since the selected effect image display is performed according to the relationship, it becomes possible to provide a player with a new method of selecting the effect image display, and the monotony of the effect image display can be eliminated.

(2) In (1), a main control unit (main control circuit 100) having the firing ball number storage means (main RAM 103) and the fluctuation number storage means (main RAM 103);
A sub-control unit (sub-control circuit 200) having the effect image display control means,
The main control unit transmits the number of game balls stored in the number-of-fired-ball storage unit and the number of changes stored in the number-of-changes storage unit to the sub-control unit.

(3) In (1), the effect image display control means, as the effect image display, suggests effect image display that suggests a relationship between the number of game balls and the number of times of symbol change display (“battle end” in FIG. 53). The character information 802 of the color) is controlled.
According to (3), for example, an effect display suggested to the player is performed, such as changing the color of the line in the ending effect at the end of the big hit game.

  According to the present invention, it is possible to provide a gaming machine that can eliminate the monotonous effect image display.

It is a perspective view which shows the external appearance in the pachinko game machine of 1st Embodiment of this invention. It is a front view which shows the external appearance in the pachinko gaming machine of 1st Embodiment of this invention. 1 is an exploded perspective view showing an overview of a pachinko gaming machine according to a first embodiment of the present invention. 1 is a front view showing an overview of a game board in a pachinko gaming machine according to a first embodiment of the present invention. It is a block diagram which shows the control circuit in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 1st Embodiment of this invention. It is a figure which shows the big hit random number determination table in the pachinko game machine of 1st Embodiment of this invention. It is a figure which shows the jackpot symbol random number determination table in the pachinko game machine of 1st Embodiment of this invention. It is a figure which shows the fluctuation pattern determination table in the pachinko game machine of 1st Embodiment of this invention. It is a figure which shows the jackpot kind determination table in the pachinko game machine of 1st Embodiment of this invention. It is a figure which shows an example of the production pattern which does not include a pseudo | simulation ream in the pachinko game machine of 1st Embodiment of this invention. It is a figure which shows an example of the production pattern containing a pseudo | simulation ream in the pachinko game machine of 1st Embodiment of this invention. It is a figure which shows an example of the effect display by the effect pattern containing the pseudo | simulation ream in the pachinko game machine of 1st Embodiment of this invention. It is a figure which shows an example of the effect display by the effect pattern containing the pseudo | simulation ream in the pachinko game machine of 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 2nd Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 2nd Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 2nd Embodiment of this invention. It is a figure which shows the example of a display of the pseudo | simulation number-of-times setting menu in the pachinko game machine of 1st Embodiment of this invention. It is a figure which shows an example of the production pattern containing the pseudo | simulation series performed in the pachinko game machine of 2nd Embodiment of this invention. It is a figure which shows an example of the production pattern containing the pseudo | simulation series performed in the pachinko game machine of 2nd Embodiment of this invention. It is a figure which shows an example of the production pattern containing the pseudo | simulation series performed in the pachinko game machine of 2nd Embodiment of this invention. It is a figure which shows the example of a display of the pseudo | simulation number-of-times setting menu in the pachinko game machine of the modification of 1st Embodiment of this invention. It is a flowchart which shows an example of the production | presentation pattern containing the pseudo | simulation series performed in the pachinko game machine of 3rd Embodiment of this invention. It is a flowchart which shows an example of the production | presentation pattern containing the pseudo | simulation series performed in the pachinko game machine of 3rd Embodiment of this invention. It is a flowchart which shows an example of the production | presentation pattern containing the pseudo | simulation series performed in the pachinko game machine of 3rd Embodiment of this invention. It is a flowchart which shows an example of the table which shows the relationship between the pseudo | simulation number of times used in the pachinko game machine of 3rd Embodiment of this invention, and the alerting | reporting reliability. It is a figure which shows an example of the production | presentation display by the production pattern containing the pseudo | simulation ream in the pachinko game machine of 3rd Embodiment of this invention. It is a figure which shows an example of the production | presentation display by the production pattern containing the pseudo | simulation ream in the pachinko game machine of 3rd Embodiment of this invention. It is a figure which shows an example of the production | presentation display by the production pattern containing the pseudo | simulation ream in the pachinko game machine of 3rd Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 4th Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 4th Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 4th Embodiment of this invention. It is a figure which shows an example of the effect display by the effect pattern containing the pseudo | simulation ream in the pachinko game machine of 4th Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 5th Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 5th Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 5th Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 5th Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 5th Embodiment of this invention. It is a figure which shows an example of the table used for the setting of an ending display in the pachinko game machine of 5th Embodiment of this invention. It is a figure which shows an example of the ending display in the pachinko game machine of 4th Embodiment of this invention. It is a front view which shows the general view of the game board in the pachinko game machine of 6th Embodiment of this invention. It is a figure which shows the big hit random number determination table in the pachinko game machine of 6th Embodiment of this invention. It is a flowchart which shows an example of the production | presentation pattern containing the pseudo | simulation series performed in the pachinko game machine of 6th Embodiment of this invention. It is a flowchart which shows an example of the production | presentation pattern containing the pseudo | simulation series performed in the pachinko game machine of 6th Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 6th Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of 6th Embodiment of this invention. It is a figure which shows an example of the effect display in the pachinko gaming machine of 6th Embodiment of this invention.

[Configuration of Pachinko machine 1]
An overview of the pachinko gaming machine 1 will be described with reference to FIGS. FIG. 1 is a perspective view showing an overview of a pachinko gaming machine 1 according to the present embodiment. FIG. 2 is a front view showing an overview of the pachinko gaming machine 1 in the present embodiment. FIG. 3 is an exploded perspective view showing an overview of the pachinko gaming machine 1 in the present embodiment. FIG. 4 is a front view of the game board 40 of the pachinko gaming machine 1 in the present embodiment.

  As shown in FIGS. 1 to 3, the pachinko gaming machine 1 includes a glass door 10, a launching device 20, a base door 30, a game board 40, a wooden frame 60, a liquid crystal display device 50 for displaying images, a payout unit 70, and a substrate. It consists of unit 80 and the like.

  The glass door 10 is pivotally attached to the base door 30 so as to be freely opened and closed. In addition, an opening 11 is formed in the center of the glass door 10, and a transparent protective glass 12 is disposed in the opening 11. The protective glass 12 is disposed so as to face the front surface of the game board 40 in a state where the glass door 10 is closed.

  Further, the glass door 10 is provided with a dish unit 13, a speaker 14, and an effect button 16 below the opening 11. The dish unit 13 is a unit body in which an upper dish 131 and a lower dish 132 positioned below the upper dish 131 are integrated. The upper plate 131 and the lower plate 132 are provided with payout openings for renting out game balls and paying out game balls (prize balls). When predetermined payout conditions are satisfied, the game balls are discharged. In particular, the upper plate 131 stores a game ball to be launched into a game area 41 described later. The speaker 14 is disposed inside the lower plate 132. The effect button 16 is disposed on the edge on the near side of the upper plate 131, and includes a ring-shaped rotating body and a push button disposed on the inner side of the rotating body.

  The launching device 20 is disposed at the lower right portion of the base door 30. The launching device 20 includes a launching handle 21 that can be operated by a player, and a panel body 22 that fits in the lower right portion of the dish unit 13. The firing handle 21 is rotatable and is provided on the front side of the panel body 22. The panel body 22 is integrated with the lower right portion of the dish unit 13 when the dish unit 13 and the launching device 20 are disposed on the base door 30. And the pachinko game can be advanced by operating the launch handle 21 by the player.

  A launch solenoid (not shown) for launching a game ball is provided on the back side of the panel body 22. Further, a touch sensor (not shown) is provided on the peripheral edge of the firing handle 21. Inside the firing handle 21 is provided a firing volume that changes the resistance value according to the amount of rotation of the firing handle 21 and changes the power supplied to the firing solenoid (not shown).

  When a touch sensor (not shown) is touched by the player, it is detected that the firing handle 21 is gripped by the player. When the firing handle 21 is gripped by the player and is turned clockwise, the resistance value of the firing volume (not shown) changes according to the turning angle, and the resistance value at this time Is supplied to a firing solenoid (not shown). As a result, game balls stored in the upper plate 131 are sequentially fired to a game area 41 (to be described later) of the game board 40, and the game is advanced. When a launch stop button (not shown) is pressed, the launch of the game ball is stopped even when the launch handle 21 is held and rotated.

  The base door 30 is pivotally attached to the wooden frame 60 so as to be openable and closable. A game board 40 is disposed on the base door 30 behind the protective glass 12.

  As shown in FIG. 4, the game board 40 is formed of a plate-shaped resin, and is formed of various materials such as an acrylic resin, a polycarbonate resin, and a methacrylic resin. Further, the game board 40 is arranged on the front side of the game area 41 where the launched game ball can roll down, the LED unit 42 arranged above the game area 41, and the lowermost part of the game area 41. And an out port 43 provided.

  The game board 40 is provided with arc-shaped guide rails 411 that define a game area 41, and a plurality of game nails 412 are driven into the game area 41. Further, the game board 40 includes a stage 413, a first start port 414a, a second start port 414b, a normal electric accessory 415, a first ball passage detector 416a, a second ball passage detector 416b, Game members such as the shutters 417a and 417b, the first big prize opening 418a, the second big prize opening 418b and the general prize winning holes 419a, 419b, 419c and 419d are arranged.

  The guide rail 411 includes an outer rail 411a and an inner rail 411b disposed on the inner side of the outer rail 411a. The stage 413 is disposed above the center of the game area 41.

  The game ball launched by the launching device 20 (see FIG. 1 etc.) is guided by the guide rail 411 and moves to the upper part of the game area 41, and its traveling direction is changed by collision with the game nail 412, the stage 413, etc. It flows down toward the lower side of the game area 41 while changing. The player, for example, drives a game ball into the left side of the stage 413 and flows the game ball down the left side of the stage 413 (so-called left-handed) and the launch handle 21 (see FIG. 1 etc.) of the launch device 20 on the right side. The pachinko game is advanced by selecting a system (so-called right-handed) in which the game ball is driven to the right side of the stage 413 and the game ball flows down the right side of the stage 413.

  The first start port 414 a is disposed below the stage 413 and below the center of the game area 41. A winning area is provided in the first start port 414a. This winning area is provided with a first start opening winning ball sensor 116a (see FIG. 5). The second start port 414b is disposed below the first start port 414a. A winning area is provided in the second start port 414b. The winning area is provided with a second start opening winning ball sensor 116b (see FIG. 5). The ordinary electric accessory 415 is a wing member that can be opened and closed provided at the second start port 414b. The second starting port 414b can be awarded when the blade member of the ordinary electric accessory 415 is open, and winning is difficult when the blade member is closed.

  The first ball passage detector 416 a is disposed on the left side of the stage 413. The second ball passage detector 416b is disposed on the right side of the stage 413. A first sphere passage detection sensor 115a (see FIG. 5) is provided in the first sphere passage detector 416a, and a second sphere passage detection sensor 115b (see FIG. 5) is provided in the second sphere passage detector 416b. It has been.

  The shutter 417a is disposed below the stage 413 and to the right of the center of the game area 41. The shutter 417b is disposed below the shutter 417a. The shutter 417a and the shutter 417b are configured to be driven in an open state or a closed state. The first big prize opening 418a is disposed on the back side (rear side) of the shutter 417a. The first grand prize opening 418a can be awarded when the shutter 417a is in the open state, and cannot be awarded when the shutter 417a is in the closed state. The second big prize opening 418b is arranged on the back side (rear side) of the shutter 417b. The second big prize opening 418b can be awarded when the shutter 417b is in the open state, and cannot be awarded when the shutter 417b is in the closed state. The general winning ports 419a and 419b are arranged on the lower left side of the stage 413. The general winning ports 419c and 419d are arranged on the lower right side of the stage 413. The first grand prize winning opening 418a and the shutter 417a and the second big winning prize opening 418b and the shutter 417b are not limited to the positions shown in the present embodiment, and may be arranged at arbitrary positions in the game area 41. The winning difficulty may be different depending on the arrangement position. Further, in this embodiment, two large winning ports, the first large winning port 418a and the second large winning port 418b, are provided as the large winning ports, but the number of large winning ports is limited to two. Instead, there may be only one grand prize opening. In addition, it is possible to arrange a large winning opening so that the degree of difficulty of winning varies depending on the combination of a plurality of large winning openings.

  The LED unit 42 includes a special symbol display device 421, a round number display device 422, a first special symbol hold display device 423a, a second special symbol hold display device 423b, a normal symbol display device 424, and a normal symbol hold display device 425. It is installed.

  The special symbol display device 421 is composed of 7-segment LEDs, and the special symbols (also referred to as identification symbols) indicated by the 7-segment LEDs are repeatedly turned on / off after a predetermined variable display start condition is satisfied. To change display and stop display. Specifically, the special symbol display device 421 receives a game ball in the first start port 414a or the second start port 414b, and the game ball is a first start port winning ball sensor 116a (see FIG. 5) or the second start port 414b. When detected by the start opening winning ball sensor 116b (see FIG. 5), the special symbol is variably displayed, and after a predetermined time has elapsed, the special symbol is stopped and displayed in a predetermined stop display mode. As described above, the special symbol display device 421 functions as a display unit that changes or stops the identification symbol.

  The round number display device 422 is configured by a 7-segment LED, and displays the number of rounds of the round game in the big hit gaming state described later.

  The first special symbol hold display device 423a is composed of four display lamps, and the number of executions of the variable display in the special symbol display device 421 triggered by winning the first start port 414a (so-called “hold number” ”,“ Holding number for special symbol ”) is displayed by turning on, turning off, or blinking.

  The second special symbol hold display device 423b is composed of four display lamps, and the number of executions of the variable display in the special symbol display device 421 triggered by winning the second start port 414b (so-called “hold number” ”,“ Holding number for special symbol ”) is displayed by turning on, turning off, or blinking. Specifically, the first special symbol hold display device 423a and the second special symbol hold display device 423b display, for example, one display when the number of executions of the variable display in the special symbol display device 421 is held once. When the display lamp is turned on and the number of executions of the variable display on the special symbol display device 421 is held twice, the two display lamps are turned on.

  The normal symbol display device 424 is composed of two display lamps, and the normal symbols shown by these display lamps are alternately turned on and off after a predetermined variable display start condition is satisfied. To change display and stop display. Specifically, in the normal symbol display device 424, a game ball passes through the first ball passage detector 416a or the second ball passage detector 416b, and the game ball passes through the first ball passage detection sensor 115a (see FIG. 5). Is detected, the normal symbol is variably displayed. After a predetermined time has elapsed, the normal symbol is stopped and displayed in a predetermined stop display mode.

  The normal symbol holding display device 425 is composed of four display lamps, and the normal symbol display device 424 is triggered by a game ball passing through the first ball passage detector 416a or the second ball passage detector 416b. The number of executions of the variable display (so-called “holding number”, “holding number for normal symbols”) is displayed by turning on, turning off, or blinking. Specifically, in the normal symbol display device 425, for example, when the number of executions of the variable display in the normal symbol display device 424 is held for one time, one display lamp is turned on, and the normal symbol display device 424 is displayed. When the number of executions of the variable display is held twice, two display lamps are lit.

  Returning to FIG. 3, the liquid crystal display device 50 is an example of display means, and is disposed behind (on the back side of) the game board 40, and its display area 51 is the center of the game board 40 as shown in FIG. 4. It is arranged further upward. In the display area 51, various kinds of images such as a derived symbol, an effect image, and a decoration image for decoration are displayed. In addition, in this embodiment, although the liquid crystal display device 50 was described as an example of a display means, this invention is not limited to this. The display means may be a plasma display, a rear projection display, a CRT display, a lamp, or the like.

  The payout unit 70 includes a payout device 71 (see FIG. 5), which will be described later. The first start port 414a, the second start port 414b, the general winning ports 419a to 419d, the first big winning port 418a and the When a game ball wins the two major winning holes 418b, a predetermined number of game balls are paid out to the upper plate 131 or the lower plate 132 according to the type of each winning port.

  The board unit 80 stores a main control circuit 100 (see FIG. 5) and a sub-control circuit 200 (see FIG. 5), which will be described later, and controls the pachinko gaming machine 1.

[Games in pachinko machine 1]
Next, a game in the pachinko gaming machine 1 will be described. In the gaming state in the present embodiment, the shutter 417a and the shutter 417b are closed, and a normal gaming state in which a game ball cannot be received in the first big prize opening 418a and the second big prize opening 418b, and the shutter 417a or shutter. 417b is in an open state, and a game ball can be received in the first grand prize opening 418a or the second big prize opening 418b, and a special game state in which a predetermined game value can be given to the player is included. The special game state includes a small hit game state and a big hit game state that can give more game value than the small hit game state. In addition, the normal gaming state includes a first gaming state that is a gaming state advantageous to the player and a second gaming state that is a gaming state that is more disadvantageous to the player than the first gaming state. In the present embodiment, the second gaming state is a normal gaming state (so-called non-probability change state) with a probability of transitioning to the special gaming state, and the first gaming state transitions to the special gaming state compared to the second gaming state. This is a gaming state (so-called probability variation state) that has a high probability of playing.

  A player generally starts a game from the normal gaming state, and drives the game ball into the game area 41 of the game board 40 by the launching device 20. When the game ball that has been placed wins the first starting port 414a or the second starting port 414b, the special symbol of the special symbol display device 421 and the identification symbol for presentation displayed on the liquid crystal display device 50 (derived symbol) change. indicate. In addition, when a game ball enters the first start port 414a or the second start port 414b during the special symbol change display, the first start port 414a or the second start ball 414a or the second start until the special symbol being changed is displayed. 2 The execution (start) of the special symbol variation display based on the game ball entering the start port 414b is put on hold. Thereafter, when the special symbol that has been variably displayed is stopped and displayed, the variable symbol of the suspended special symbol is started.

  An upper limit is set for the number of times the execution of the special symbol variation display is suspended, and in this embodiment, the special symbol variation display by entering the first start port 414a and the second start port 414b. The upper limit of the number of holds is 4 times. Therefore, a maximum of 8 holds is possible.

  Further, as another condition (starting the variable display of a predetermined special symbol), the special symbol start condition is satisfied when the special symbol is stopped and displayed. That is, every time a predetermined special symbol variable display start condition is satisfied, the special symbol variable display is started.

  Then, when the special symbol stopped and displayed on the special symbol display device 421 is in a specific stop display mode, the normal gaming state is shifted to the special gaming state. Among the specific stop display modes, the stop display mode for shifting to the big hit gaming state is the big hit, and the stop display mode for shifting to the small hit gaming state is the small hit. Moreover, the stop display mode of the special symbols other than the big hit or the small hit is a lost symbol. When the lost symbol is stopped and displayed, the normal gaming state is maintained without shifting to the special gaming state. As described above, a game in which a special symbol is variably displayed and then stopped and the game state is shifted or maintained according to the result is referred to as a “special symbol game”.

  In the display area 51 of the liquid crystal display device 50, an effect image related to the special symbol displayed on the special symbol display device 421 is displayed. For example, during the variable display of the special symbol display device 421, except for a specific case, in the display area 51 of the liquid crystal display device 50, a derived symbol composed of a number as an example of the identification symbol is displayed in a variable manner. In addition, the special symbol display device 421 stops and displays the special symbol, and the derived symbol is also stopped and displayed in the display area 51 of the liquid crystal display device 50. As described above, after the identification symbol is variably displayed on the liquid crystal display device 50 in synchronization with the special symbol game on the special symbol display device 421, it is stopped and displayed, and the identification symbol game is executed.

  Further, in the special symbol display device 421, when the special symbol that is stopped and displayed is in a specific stop display mode, an effect image that allows the player to grasp that it is a win is displayed in the display area 51 of the liquid crystal display device 50. The Specifically, when the special symbol is stopped and displayed in a specific display mode corresponding to a big hit that can be obtained by many outgoing balls, for example, in the special symbol display device 421, the display area 51 of the liquid crystal display device 50 is displayed. The combination of the identification symbols for the effect displayed in is a specific display mode (for example, a mode in which all the same symbols are arranged in a plurality of symbol rows and stopped and displayed), and further, the effect image showing the big hit Is displayed in the display area 51 of the liquid crystal display device 50.

  When the special symbol becomes a specific stop display mode in the special symbol display device 421 and the gaming state is shifted to the special gaming state, the shutter 417a or the shutter 417b is in an open state in which it is easy to accept the game ball. Driven. As a result, the first big prize opening 418a or the second big prize opening 418b is in an open state in which it is easy to accept a game ball.

  The first big prize opening 418a or the second big prize opening 418b provided on the back side (rear) of the shutter 417a or the shutter 417b has an area (not shown) having a count sensor 113 (see FIG. 5). The shutter 417a or the shutter 417b is driven to an open state until a predetermined number (for example, seven) of game balls wins in the area or a predetermined time (for example, about 30 seconds) elapses. Then, when a condition for winning a predetermined number of game balls to the first big prize opening 418a or the second big prize opening 418b or the elapse of a predetermined time is satisfied in the open state, the shutter 417a or the shutter 417b is driven, The first big prize opening 418a or the second big prize opening 418b is in a closed state in which it is difficult to accept a game ball. In the present embodiment, in the special gaming state, the transition from the closed state to the open state is repeated 15 times by driving the shutter 417a or the shutter 417b in the first grand prize port 418a or the second grand prize port 418b. However, the present invention is not limited to this, and an open state in which a game ball can be easily received may be set to any number of times such as once or twice.

  Further, when the specific stop display mode in the special symbol display device 421 is a big hit, the gaming state shifts to the big hit gaming state in the special gaming state. In the jackpot game state, a game in which the transition from the closed state to the open state is repeated 15 times for the first grand prize port 418a or the second grand prize port 418b is one round, and a round game in which this round is repeated. Done. Such a round game is counted as the number of rounds such as “1” round and “2” round. For example, the first round game is also referred to as the first round and the second round is also referred to as the second round. In the present embodiment, the number of rounds in the big hit gaming state is 10 rounds or 16 rounds, but is not limited to this, and the number of rounds can be any number.

  In addition, when the specific stop display mode in the special symbol display device 421 is a small hit, the gaming state shifts to the small hit gaming state in the special gaming state. In the small hit game state, a game in which the transition from the closed state to the open state of the first big prize port 418a or the second big prize port 418b is repeated 15 times is performed only once. That is, in the small hit game state, the round game is not performed unlike the big hit game state. When the big hit gaming state ends, the first gaming state (probability variation state) or the second gaming state (non-probability variation state) may be controlled as the normal gaming state. Further, when the small hit gaming state is ended, the gaming state is not more advantageous than the gaming state when the small hit gaming state is won. For this reason, there is no transition of the gaming state in the normal gaming state triggered by winning the small hit gaming state. For example, when the gaming state when winning the small hit gaming state is the first gaming state, The gaming state after the end of the winning game state is the first gaming state. When the gaming state when the small winning game state is won is the second gaming state, the gaming state after the end of the winning game state is the second gaming state. State.

  In addition, when a game ball wins the first start port 414a, the second start port 414b, the general winning ports 419a to 419d, the first big winning port 418a and the second big winning port 418b, it depends on the type of each winning port. A predetermined number of game balls are paid out to the upper plate 131 or the lower plate 132 by the payout unit 70.

  Further, when a game ball driven into the game area 41 by the player passes through the first ball passage detector 416a or the second ball passage detector 416b, the display lamp of the normal symbol display device 424 is variably displayed. In addition, when a game ball passes through the first ball passage detector 416a or the second ball passage detector 416b during the normal symbol variation display, the normal symbol hold display device 425 switches the display mode to display the variation display. Until the normal symbol is stopped and displayed, the execution (start) of the normal symbol variation display based on the passing of the game ball to the first ball passage detector 416a or the second ball passage detector 416b is suspended. After that, when the normal symbol that has been variably displayed is stopped and displayed, the variably displayed normal symbol that has been suspended is started. When the normal symbol that is stopped and displayed on the normal symbol display device 424 is in a state indicating a hit, the blade member of the ordinary electric accessory 415 provided at the second start port 414b is opened for a predetermined time. It becomes. As described above, a game in which the normal symbol is variably displayed and then stopped is displayed, and the open / closed state of the normal electric accessory 415 (see FIG. 4) varies depending on the result, which is referred to as a “normal symbol game”.

[Electric configuration of gaming machine]
A block diagram showing a control circuit of the pachinko gaming machine 1 in the present embodiment is shown in FIG. As shown in FIG. 5, the pachinko gaming machine 1 mainly includes a main control circuit 100 that controls a game and a sub-control circuit 200 that controls an effect according to the progress of the game.

  The main control circuit 100 includes a main CPU 101, a main ROM 102 (read only memory), and a main RAM 103 (read / write memory).

  The main CPU 101 is connected to a main ROM 102, a main RAM 103, and the like, and has a function of executing various processes in accordance with programs stored in the main ROM 102.

  The main ROM 102 stores a program for controlling the operation of the pachinko gaming machine 1 by the main CPU 101, for example, a program for causing the main CPU 101 to execute the processes shown in FIGS. 6 to 15, various tables, and the like. Yes.

  The main RAM 103 has a function of storing various flags and variable values as a temporary storage area of the main CPU 101. In this embodiment, the main RAM 103 is used as a temporary storage area of the main CPU 101. However, the present invention is not limited to this, and any readable / writable storage medium may be used.

  The main control circuit 100 also provides a command for a reset clock pulse generation circuit 104 that generates a clock pulse of a predetermined frequency, an initial reset circuit 105 that generates a reset signal when the power is turned on, and a sub control circuit 200 described later. IC for serial communication 106 is provided. The reset clock pulse generation circuit 104, the initial reset circuit 105, and the serial communication IC 106 are connected to the main CPU 101.

  The reset clock pulse generation circuit 104 generates a clock pulse every predetermined period (for example, 2 milliseconds) in order to execute a system timer interrupt process to be described later.

  The initial reset circuit 105 includes a capacitor and a watchdog timer, and transmits a reset signal to the main CPU 101 when the voltage applied to the capacitor reaches a certain value. The initial reset circuit 105 receives a predetermined control signal from the main CPU 101 and discharges it to release the voltage applied to the capacitor.

  The serial communication IC 106 is connected to the main CPU 101, the sub control circuit 200, and the payout / launch control circuit 300, and includes a sub control board buffer and a payout / fire control circuit buffer.

  Various devices are connected to the main control circuit 100. For example, various devices that respond to signals from the main control circuit 100 include a special symbol display device 421 that performs variable display of special symbols in a special symbol game, a round number display device 422 that displays the number of rounds in a round game, and a special symbol. A first special symbol hold display device 423a and a second special symbol hold display device 423b for displaying the number of reserved special symbols in a game variable display, and a normal symbol display device for performing variable display of a normal symbol as an identification symbol in a normal symbol game 424, a normal symbol holding display device 425 for displaying the number of holdings for variable display of the normal symbols in the normal symbol game, a normal electric accessory solenoid 111 for opening or closing the blade member of the normal electric accessory 415, a shutter 417a is driven, and the first grand prize opening 418a is opened or closed. That the first special winning opening solenoid 112a, drives the shutter 417b, such as the second special winning opening solenoid 112b of the second special winning opening 418b to an open state or closed state is connected. In addition, a call device (not shown) having a function of calling a hall clerk and a function of displaying the number of hits and an external terminal board used for data transmission to a hall computer that manages pachinko gaming machines throughout the hall are connected.

  Various sensors are connected to the main control circuit 100. For example, the main control circuit 100 includes a count sensor 113 that supplies a predetermined detection signal to the main control circuit 100 when a game ball is won in the first big prize opening 418a or the second big prize opening 418b. When a game ball wins in the mouth 419, when a game ball wins the general winning ball sensor 114 and the first ball passage detector 416a that supply a predetermined detection signal to the main control circuit 100, a predetermined detection signal is given. A second ball passage detection sensor 115b that supplies a predetermined detection signal to the main control circuit 100 when a game ball wins the first ball passage detection sensor 115a and the second ball passage detector 416b supplied to the main control circuit 100. When a game ball wins the first start port 414a, the first start port winning ball sensor 116a that supplies a predetermined detection signal to the main control circuit 100, and the game ball enters the second start port 414b. A second start-up winning ball sensor 116b for supplying a predetermined detection signal to the main control circuit 100, a backup clear switch 117 for clearing backup data in the event of a power interruption in accordance with the operation of the game hall manager, A discharge ball sensor 118 that supplies a predetermined detection signal to the main control circuit 100 when a game ball discharged to the outside of the pachinko gaming machine 1 is detected after being launched on the game board 40 is connected. In the present embodiment, winning means that a game ball passes through an area where each sensor is provided.

  The main control circuit 100 is connected to a payout / launch control circuit 300. The payout / launch control circuit 300 is connected to a payout device 71 for paying out game balls, a launch device 20 for launching game balls, and a card unit 400. The card unit 400 can be transmitted / received to / from the lending operation unit 401 that outputs a signal for requesting the card unit 400 to lend a game ball by the player's operation.

  The payout / launch control circuit 300 receives a prize ball control command supplied from the main control circuit 100 and a lending ball control signal supplied from the card unit 400, and transmits a predetermined signal to the payout device 71. The paying device 71 pays out the game ball. In addition, when the launch handle 21 is gripped by the player and is rotated in the clockwise direction, the payout / launch control circuit 300 supplies power to the launch solenoid according to the rotation angle, and the game Control to fire the ball.

  Further, a sub control circuit 200 is connected to the main control circuit 100. The sub-control circuit 200 performs display control in the liquid crystal display device 50, control related to sound generated from the speaker 14, control of lamps including decoration lamps, and the like according to various commands supplied from the main control circuit 100. .

  In the present embodiment, the main control circuit 100 is configured not to supply commands to the sub control circuit 200 and to prevent signals from being supplied from the sub control circuit 200 to the main control circuit 100. However, the configuration may be such that a signal can be transmitted from the sub control circuit 200 to the main control circuit 100.

  The sub control circuit 200 includes a sub CPU 201, a program ROM 202, a work RAM 203, an RTC 204, a display control circuit 210 for performing display control in the liquid crystal display device 50, a sound control circuit 220 for performing control related to sound generated from the speaker 14, and a decoration lamp. The lamp control circuit 230 for controlling the lamp 15 including the above, and the operation means control circuit 240 for receiving an operation signal based on the player's operation from the effect button 16. The sub control circuit 200 executes an effect corresponding to the progress of the game in accordance with a command from the main control circuit 100.

  The sub CPU 201 has a function of executing various processes in accordance with programs stored in the program ROM 202. In particular, the sub CPU 201 controls the sub control circuit 200 in accordance with various commands supplied from the main control circuit 100.

  The program ROM 202 stores a program and various tables for controlling the game effects of the pachinko gaming machine 1 by the sub CPU 201.

  In the present embodiment, the main ROM 102 and the program ROM 202 are used as storage means for storing programs, tables, and the like. However, the present invention is not limited to this, and a storage medium that can be read by a computer having control means. Any other form may be used, for example, it may be recorded on a storage medium such as a hard disk device, a CD-ROM, a DVD-ROM, or a ROM cartridge. Further, these programs may not be recorded in advance, but may be downloaded after the power is turned on and recorded in the work RAM 203 or the like. Furthermore, each program may be recorded on a separate storage medium.

  The work RAM 203 stores various flag and variable values as a temporary storage area of the sub CPU 201. In this embodiment, the work RAM 203 is used as a temporary storage area of the sub CPU 201. However, the present invention is not limited to this, and any readable / writable storage medium may be used. The RTC 204 measures the current time.

  The display control circuit 210 is a circuit that performs display control of the liquid crystal display device 50, an image data processor (hereinafter referred to as VDP), an image data ROM 211 that stores data for generating various image data, A frame buffer for buffering image data, a D / A converter for converting image data as an image signal, and the like are included.

  The display control circuit 210 is a device that can perform various processes for displaying an image on the liquid crystal display device 50 in accordance with data supplied from the sub CPU 201. In response to an image display command supplied from the sub CPU 201, the display control circuit 210 displays on the liquid crystal display device 50 various image data such as identification symbol image data indicating the identification symbol, background image data, and production image data. The image data to be stored is temporarily stored in the frame buffer.

  Then, the display control circuit 210 supplies the image data stored in the frame buffer to the D / A converter at a predetermined timing. The D / A converter converts image data as an image signal, and supplies the image signal to the liquid crystal display device 50 at a predetermined timing, whereby an image is displayed on the liquid crystal display device 50. That is, the display control circuit 210 performs control to display an image related to the game on the liquid crystal display device 50.

  The audio control circuit 220 includes a sound source IC that performs control related to audio, an audio data ROM that stores various audio data, an amplifier (hereinafter referred to as AMP) for amplifying an audio signal, and the like.

  The sound source IC controls sound generated from the speaker 14. The sound source IC selects one sound data from a plurality of sound data stored in the sound data ROM in accordance with the sound generation command supplied from the sub CPU 201. The sound source IC reads the selected sound data from the sound data ROM, converts the sound data into a predetermined sound signal, and supplies the sound signal to the AMP. The AMP amplifies the sound signal and generates sound from the speaker 14.

  The lamp control circuit 230 includes a drive circuit for supplying a lamp control signal, a decoration data ROM that stores a plurality of types of lamp decoration patterns, and the like.

  The operation means control circuit 240 transmits the operation signal received from the effect button 16 to the sub CPU 201. The sub CPU 201 supplies data for performing an effect corresponding to the operation signal to the display control circuit 210 and the like.

  Next, processing executed by the main control circuit 100 and the sub control circuit 200 of this embodiment will be described. First, processing executed by the main CPU 101 of the main control circuit 100 will be described. When the power is turned on, the main CPU 101 reads a program from the main ROM 102 and executes main control main processing. Further, the main CPU 101 may interrupt the main control main process and execute the system timer interrupt process even when the main control main process is being executed. The main CPU 101 generates a clock pulse every predetermined period (for example, 2 milliseconds), and executes a system timer interrupt process accordingly.

[System timer interrupt processing]
The system timer interrupt process of the main CPU 101 will be described with reference to FIGS. As shown in FIG. 6, in step S10, processing for saving each register is performed. In this process, the main CPU 101 performs a process for saving a register. If this process ends, the process moves to a step S11.

  In step S11, random number update processing is performed. In this process, the main CPU 101 performs a process of updating the random number. For example, the main CPU 101 updates random numbers such as a jackpot determination random number counter, a jackpot symbol random number counter, a normal symbol determination random number counter, and an effect condition determination random number counter. Note that the jackpot determination random number counter and the jackpot symbol random number counter are not fair if the update timing of the counter value is indefinite. Therefore, it is updated at a fixed timing every 2 msec to ensure this. Like to do. If this process ends, the process moves to a step S12.

  In step S12, switch input detection processing is performed. In this process, the main CPU 101 performs a process for determining whether or not there is an input to the switch. For example, the main CPU 101 uses the count sensors 113 (see FIG. 5) provided in the first grand prize winning opening 418a and the second big winning prize opening 418b (see FIG. 4), and general winning prize winning openings 419a, 419b, 419c, and 419d (see FIG. 5). 4) and the first ball passing detection sensor 115a provided in the first ball passing detector 416a and the second ball passing detector 416b (see FIG. 4). , Second ball passage detection sensor 115b (see FIG. 5), first start port winning ball sensor 116a provided at first start port 414a and second start port 414b (see FIG. 4), second start port winning ball By receiving a detection signal from the sensor 116b (see FIG. 5), it is determined whether each switch has detected a game ball. If the main CPU 101 determines that it has been detected, the main CPU 101 updates the big prize opening prize ball counter, the general winning opening prize ball counter, the start opening prize ball counter, and the like according to the detection. Details of the switch input processing will be described later. If this process ends, the process moves to a step S13.

  In step S13, timer update processing is performed. In this process, the main CPU 101 waits for synchronization between the main control circuit 100 and the sub-control circuit 200, a first big prize opening 418a and a second big prize opening 418b (open when a big hit occurs. A process of updating various timers such as a big prize opening time timer for measuring the opening time of FIG. 4) is executed. If this process ends, the process moves to step S14.

  In step S14, command output processing is performed. In this process, the main CPU 101 supplies various commands to the sub control circuit 200. Examples of these various commands include a demo display command derived and displayed on the liquid crystal display device 50, a derived symbol designation command described later, a variation pattern designation command described later, a jackpot type command described later, a jackpot start command described later, A small hitting start command to be performed, a starting opening prize command to be described later, a symbol stop command to be described later, a launch ball command to be described later. In this process, the main CPU 101 supplies, to the sub-control circuit 200, data indicating the value of the probability variation state variation count counter described later, and data indicating the value of the time-short state variation count counter described later, in addition to various commands. . In addition, the main CPU 101 drives the first big prize opening solenoid 112a (see FIG. 5) that drives the shutter 417a of the first big prize opening 418a, and the second big prize opening solenoid 112b that drives the shutter 417b of the second big prize opening 418b. (Refer to FIG. 5), a solenoid power supply for driving the ordinary electric accessory solenoid 111 (see FIG. 5) for opening and closing the blade member of the ordinary electric accessory 415 is supplied. Further, in the starting opening winning detection process (see FIG. 8), which will be described later, the variation pattern of the identification symbol (derived symbol) for effect displayed in the display area 51 (see FIG. 4) of the liquid crystal display device 50 is determined. When the main CPU 101 generates a change pattern designation command indicating the determination result, the main CPU 101 supplies the change pattern designation command to the sub-control circuit 200. If this process ends, the process moves to a step S15.

  In step S15, game information output processing is performed. In this process, the main CPU 101 sends game information, which is information related to the game, processed by the main control circuit 100, the sub control circuit 200, the payout / launch control circuit 300, etc., to the sub control circuit 200, the payout / fire control circuit. 300, output to an external device (for example, hall computer or calling device). When this process ends, the process moves to a step S16.

  In step S16, processing for restoring each register is performed. In this processing, the main CPU 101 performs processing for restoring each register to the address before the interrupt processing. When this process is finished, this subroutine is finished.

[Switch input detection processing]
A subroutine (switch input detection process) executed in step S12 of FIG. 6 will be described with reference to FIG. In step S20, a start opening winning detection process is performed. In this process, the main CPU 101 includes a first start port winning ball sensor 116a and a second start port winning ball sensor 116b (see FIG. 5) provided at the first start port 414a and the second start port 414b (see FIG. 4). If the detection signal is received, the jackpot determination random number value and the jackpot symbol random number value are acquired, the maximum number of four is held, and the number of reserved symbols related to the special symbol is added by one, and the payout information is stored in a predetermined area of the main RAM 103. set. Details of the start opening winning detection process will be described later. If this process ends, the process moves to a step S21.

  In step S21, a general winning opening passing detection process is performed. In this process, when the main CPU 101 has received a detection signal from the general winning ball sensor 114 (see FIG. 5) provided in the general winning openings 419a, 419b, 419c, 419d (see FIG. 4), The payout information corresponding to the winnings of the mouths 419a, 419b, 419c, 419d is set in a predetermined area of the main RAM 103. If this process ends, the process moves to a step S22.

  In step S22, a special winning opening passing detection process is performed. In this process, the main CPU 101 receives the detection signal from the count sensor 113 (see FIG. 5) provided in the first big prize opening 418a and the second big prize opening 418b (see FIG. 4). The payout information corresponding to the winning of the first grand prize opening 418a and the second big prize opening 418b is set in a predetermined area of the main RAM 103. When this process ends, the process moves to a step S23.

  In step S23, a ball passage detector passage detection process is performed. In this process, the main CPU 101 includes a first sphere passage detection sensor 115a and a second sphere passage detection sensor 115b (FIG. 5) provided in the first sphere passage detector 416a and the second sphere passage detector 416b (see FIG. 4). If a detection signal is received from the reference), a lottery result (random number value) relating to the normal symbol is acquired, and the upper limit is four, and the normal symbol holding memory number counter (holding number) stored in the main RAM 103 is stored. Add "1". If this process ends, if this process ends, the process moves to step S24.

  In step S24, a discharge ball detection process is performed. In this process, the main CPU 101 stores a firing number command in the main RAM 103 when receiving a detection signal from the discharge ball sensor 118 (see FIG. 5). The firing number command is supplied to the sub-control circuit 200 in the command output process of step S14. The discharge ball sensor 118 detects all game balls that have passed through the game board 40, and the number of game balls detected by the discharge ball sensor 118 is the number of game balls that have been driven into the game board 40, that is, Equal to the number of shot balls. When this process is finished, this subroutine is finished.

[Start-up winning detection processing]
The subroutine (start opening prize detection process) executed in step S20 in FIG. 7 will be described with reference to FIG. In step S30, a process is performed to determine whether or not the first start opening winning ball sensor has detected. In this process, the main CPU 101 determines whether or not a detection signal has been received from the first start opening winning ball sensor 116a. If a detection signal has been received from the first start opening winning ball sensor 116a, the process proceeds to step S31. If a detection signal has not been received from the first starting opening winning ball sensor 116a, the process proceeds to step S39. Move processing.

  In step S31, a payout information set process is performed. In this process, the main CPU 101 sets payout information corresponding to the winning of the first start port 414a (see FIG. 4) in a predetermined area of the main RAM 103. When this process ends, the process moves to a step S32.

  In step S32, a process is performed to determine whether or not the number of first start opening prizes held is smaller than "4". In this process, the main CPU 101 determines whether or not the reserved number based on the winning of the first start port 414a (see FIG. 4) is smaller than “4”. The process moves to S33, and if the number of holds is “4” or more, the process moves to step S39.

  In step S33, a process of adding “1” to the reserved number of first start opening winnings is performed. In this process, the main CPU 101 performs a process of adding “1” to the value of the reserved number based on the winning of the first starting port 414a (see FIG. 4) stored in the main RAM 103. If this process ends, the process moves to a step S34.

  In step S34, random number acquisition / storage processing is performed. In this process, the main CPU 101 extracts the jackpot determination random number value of the special symbol game from the jackpot determination random number counter (so-called special symbol lottery), and further extracts the jackpot symbol random number value from the jackpot symbol random number counter. Then, the main CPU 101 stores the extracted jackpot determination random number value and the jackpot symbol random number value in the main RAM 103 as a random number value based on the winning of the first starting port 414a (see FIG. 4). The process to memorize is performed. In the present embodiment, the first special symbol start storage area is from the first special symbol start storage area (0) to the first special symbol start storage area (4), and the first special symbol start storage area (0). The determination result based on the random number for hit determination stored in is derived and displayed by a special symbol, and various random values acquired by winning the first starting port 414a (see FIG. 4) during the variation of the special symbol are: The first special symbol start storage area (1) to the first special symbol start storage area (4) are sequentially stored. If this process ends, the process moves to a step S35.

  In step S35, special symbol determination processing is performed. In this process, the main CPU 101 refers to the jackpot random number determination table (see FIG. 20) and the jackpot symbol random number determination table (see FIG. 21) based on the jackpot determination random number value and the jackpot symbol random number value extracted in step S34. Then, the special symbol to be stopped and displayed on the special symbol display device 421 is determined, and data indicating the special symbol is stored in a predetermined area of the main RAM 103. In the present embodiment, the special symbol includes a big hit symbol indicating that the jackpot is won, a small hit symbol indicating that the jackpot is won, and a miss indicating that neither the big hit or the small hit is won. And a design.

[Big hit random number judgment table]
Here, the jackpot random number determination table will be described with reference to FIG. In the present embodiment, the jackpot random number determination table (the first jackpot random number determination table (the first jackpot random number determination table) referred to when a random value based on the winning of the first start port 414a (see FIG. 4) shown in FIG. 1 start port), and a jackpot random number determination table (second start port) to be referred to when a random value based on the winning of the second start port 414b (see FIG. 4) is extracted as shown in FIG. Are stored in the main ROM 102. In the jackpot random number determination table, determination value data is associated with a jackpot determination random value for which a predetermined width is set for each probability variation flag indicating whether the gaming state is a probability variation state or a non-probability variation state. Here, the random number for determining the big hit is 65536 (0 to 65535), and the randomness for determining whether or not the big win is the result of the lottery triggered by winning the first starting port 414a or the second starting port 414b. A numerical value, specifically, a random value indicating a lottery result of a special symbol. The probability variation flag is a flag that is stored in the main RAM 103 and indicates whether or not the probability variation state is selected as the gaming state after the big hit gaming state. When the value is “0”, the probability variation state is not established. (Non-probable change state), and a value of “1” indicates that the state is probabilistic change state. As described above, whether or not the state is the probability variation state is flag-managed by the main control circuit 100, and the jackpot probability varies depending on whether or not the state is the probability variation state. Further, the selection rate shown in FIG. 20 represents the probability that the corresponding determination value data is selected.

  Specifically, in the big hit random number determination table (first start port) shown in FIG. 20A, when the probability variation flag is “0” (non-probability variation state), the big hit determination random number value “777-943” (width 167) ) Is associated with the big hit determination value data, the big hit determination random number value “1-300” (width 300) is associated with the small hit determination value data, and the random number value other than these is associated with the loss determination value data. ing. In the jackpot random number determination table (first start port), when the probability variation flag is “1” (probability variation state), the jackpot determination value data is associated with the random number value for the jackpot determination “777-1277” (width 500), The big hit determination random number value “1-300” (width 300) is associated with the small hit determination value data, and other random number values are associated with the loss determination value data. As described above, in the present embodiment, when the first starting port 414a is won in the non-probability variation state, the probability of winning a big hit (hereinafter also referred to as a big hit probability) is 1/392, and the probability of being a big hit (hereinafter referred to as a big hit probability) , Also called a small hit probability) is 1/218. On the other hand, when winning in the first start port 414a in the probability variation state, the big hit probability is 1/131 and the small hit probability is 1/218.

  Further, the big hit random number determination table (second start port) shown in FIG. 20B is a big hit for the big hit determination random number value “777-943” (width 167) when the probability variation flag is “0” (non-probability variation state). The determination value data is associated, and the loss determination value data is associated with other random number values. In the jackpot random number determination table (second starting port), when the probability variation flag is “1” (probability variation state), the jackpot determination random number value “777-1277” (width 500) is associated with the jackpot determination value data. Loss determination value data is associated with random numbers other than this. As described above, in this embodiment, when the second start port 414b is won in the non-probability variation state, the probability of winning a big hit (hereinafter also referred to as a big hit probability) is 1/392. On the other hand, when winning in the first start port 414a in the probability variation state, the big hit probability is 1/131, and the small win is not won.

[Big hit design random number judgment table]
Next, the jackpot symbol random number determination table will be described with reference to FIG. In the present embodiment, the jackpot symbol random number determination table shown in FIG. 21A is a jackpot symbol random number determination table that is referred to when a random number value based on the winning of the first start port 414a (see FIG. 4) is extracted. (First start port) and a jackpot symbol random number determination table (second start) that is referred to when a random number value based on the winning of the second start port 414b (see FIG. 4) shown in FIG. 21B is extracted. Are stored in the main ROM 102. In the jackpot symbol random number determination table, a symbol designation command is associated with a jackpot symbol random value having a predetermined width. Here, the jackpot symbol random number value represents a random number value that determines the jackpot symbol when the lottery result is a jackpot. The symbol designating command represents a jackpot symbol designating command corresponding to the jackpot symbol random number value.

  Specifically, in the jackpot symbol random number determination table (first start port) shown in FIG. 21A, the symbol designation command “z0” is associated with the jackpot symbol random number value “0 to 19”, and the jackpot symbol random number value Symbol designation command “z1” is associated with “20 to 39”, symbol designation command “z2” is associated with jackpot symbol random value “40 to 59”, symbol designation is designated with jackpot symbol random value “60 to 79” The command “z3” is associated, and the symbol designation command “z4” is associated with the jackpot symbol random number value “80 to 99”. As described above, in this embodiment, when winning the first start opening 414a and winning a big hit, the symbol designation commands “z0” to “z4” are equally selected with a probability of 20/100.

  Further, in the jackpot symbol random number determination table (second start port) shown in FIG. 21B, the symbol designation command “z0” is associated with the jackpot symbol random number value “0-19”, and the jackpot symbol random number value “20˜ 99 ”is associated with the symbol designation command“ z4 ”. Thus, in this embodiment, when winning the second start port 414b and winning a big hit, the symbol designation command “z0” is selected at 20/100, and the symbol designation command “z4” is selected at 80/100. Is done. That is, when winning the second start opening 414b and winning the big win, the probability that the symbol designation command “z4” is selected is higher than when winning the first start opening 414a and winning the big win.

  Returning to FIG. 8, in step S35, in detail, the main CPU 101 determines the jackpot random number determination table (first start port) shown in FIG. 20A and the jackpot symbol random number determination table (first table) shown in FIG. 1 start opening), the symbol designating command associated with the special symbol to be stopped and displayed on the special symbol display device 421 is determined based on the jackpot determination random number extracted in step S34. Specifically, the main CPU 101 determines the jackpot extracted in step S34 when the extracted jackpot determination random number value is associated with the jackpot determination value data in the jackpot random number determination table (first start port). Based on the symbol random number value, the jackpot symbol random number determination table (first start port) is referred to and one of symbol designation commands “z0” to “z4” is selected. Further, the main CPU 101 determines that the symbol designation command “z11” (see FIG. 11) when the extracted jackpot determination random number value is associated with the small hit determination value data in the jackpot random number determination table (first start port). 22). When the extracted big hit determination random number value is associated with the loss determination value data in the big hit random number determination table (first start port), the main CPU 101 determines the symbol designation command “z5” (FIG. 22). Select Browse. If this process ends, the process moves to a step S36.

  In step S36, jackpot determination processing is performed. In this process, the main CPU 101 refers to the jackpot random number determination table (first start port) shown in FIG. 20A, and associates the jackpot determination random number extracted in step S34 with the jackpot determination value data. Judge whether or not. If this process ends, the process moves to a step S37.

  In step S37, a variation pattern determination process is performed. In this process, the main CPU 101 extracts a fluctuation pattern random value, and determines a special symbol fluctuation pattern based on the fluctuation pattern random value, the special symbol determined in step S35, and the result of the jackpot determination process in step S36. The fluctuation pattern is determined with reference to the fluctuation pattern determination table (see FIG. 22) for storing the data, and stored in a predetermined area of the main RAM 103. The main CPU 101 determines the variation display mode of the special symbol in the special symbol display device 421 based on such data indicating the variation pattern.

[Variation pattern determination table]
Here, the variation pattern determination table will be described with reference to FIG. The variation pattern determination table is stored in the main ROM 102, and symbol design commands (“z0”, “z1”, “z2”, “z3”, “z4”, “z5”, “z11”) are added to a plurality of types of variation patterns. ) And the winning type (“losing”, “small hit”, “big hit”) are associated with each other. In the variation pattern determination table, each variation pattern is associated with data indicating the variation time of the special symbol.

  Returning to FIG. 8, in step S <b> 37, the main CPU 101 supplies data indicating the determined variation pattern to the special symbol display device 421. The special symbol display device 421 variably displays the special symbol for the variation time defined in the variation pattern determination table (see FIG. 22) based on the data indicating the variation pattern, and is associated with the symbol designation command. Stop display. Data indicating the variation pattern is supplied from the main CPU 101 of the main control circuit 100 to the sub CPU 201 of the sub control circuit 200 as a variation pattern designation command. Then, the sub CPU 201 of the sub control circuit 200 executes an effect display according to the received variation pattern designation command. The data indicating the variation pattern includes pseudo continuous designation data for designating execution of the pseudo continuous effect. When the sub control circuit 200 receives the pseudo continuous designation data, the sub CPU 201 of the sub control circuit 200 executes the pseudo continuous effect. The pseudo-continuous effect means that the identification information is temporarily stopped (without being completely stopped) after the variation display of the identification information (identification symbol 52 described later) starts to fluctuate for a predetermined time within the variation time of the identification information. The pattern is finely moved and is not completely stopped), and changes (re-changes) from this temporary stop state, and this temporary stop and re-change are continued at least once until the identification information of all the columns is stopped. This is a specific variation pattern to be performed. Whether or not to execute the pseudo-continuous performance is determined by the main CPU 101 performing random number lottery or the like. In the pseudo-continuous effect, random numbers for determining the pseudo-continuous effect are distributed so that the pseudo-continuous effect is easily executed when a variation pattern having a relatively long variation time is selected. According to the present embodiment, as shown in FIG. 21, in the case of a big hit, since a fluctuation pattern having a relatively long fluctuation time can easily be handled, when the pseudo-continuous effect is executed, the degree of expectation for the big hit Is higher than the normal performance. That is, the greater the number of consecutive pseudo-reams, the higher the degree of expectation for the big hit. If this process ends, the process moves to a step S38.

  In step S38, a command set process for increasing the number of reserves for the first start opening prize is performed. In this process, the main CPU 101 sets a reserved number increase command for driving the first special symbol hold display device 423a (see FIG. 4) in accordance with the process of adding “1” to the hold number value in step S33. Processing to be stored in the RAM 103 is performed. The main CPU 101 supplies this reserved number increase command to the first special symbol hold display device 423a. The first special symbol hold display device 423a turns on the display lamp based on the supplied hold number increase command. If this process ends, the process moves to a step S39.

  In step S39, a process is performed to determine whether or not the second start opening winning ball sensor has detected. In this process, the main CPU 101 determines whether or not a detection signal has been received from the second start opening winning ball sensor 116b. If a detection signal has been received from the second start-port winning ball sensor 116b, the process proceeds to step S40. If a detection signal has not been received from the second start-port winning ball sensor 116b, this subroutine is executed. finish.

  In step S40, a payout information set process is performed. In this process, the main CPU 101 sets payout information corresponding to the winning of the second start port 414b (see FIG. 4) in a predetermined area of the main RAM 103. If this process ends, the process moves to a step S41.

  In step S41, a process is performed to determine whether or not the number of second start opening prizes held is smaller than “4”. In this process, the main CPU 101 determines whether or not the reserved number based on the winning of the second start port 414b (see FIG. 4) is smaller than “4”. The processing moves to S42, and when the number of reservations is “4” or more, this subroutine is finished.

  In step S42, a process of adding “1” to the number of reserved second start opening winnings is performed. In this process, the main CPU 101 performs a process of adding “1” to the value of the reserved number based on the winning of the second starting port 414b (see FIG. 4) stored in the main RAM 103. If this process ends, the process moves to a step S43.

  In step S43, random number acquisition / storage processing is performed. In this process, the main CPU 101 extracts the jackpot determination random number value of the special symbol game from the jackpot determination random number counter (so-called special symbol lottery), and further extracts the jackpot symbol random number value from the jackpot symbol random number counter. Then, the main CPU 101 stores, in the main RAM 103, the extracted random number value for jackpot determination and the jackpot symbol random number value, a random number value based on the winning of the second starting port 414b (see FIG. 4) in the main RAM 103. The process to memorize is performed. In the present embodiment, the second special symbol start storage area is from the second special symbol start storage area (0) to the second special symbol start storage area (4), and the second special symbol start storage area (0). The result of the determination based on the random number for determining the hit stored in is displayed with a special symbol, and various random values acquired by winning the second starting port 414b (see FIG. 4) during the variation of the special symbol are: The second special symbol start storage area (1) to the second special symbol start storage area (4) are sequentially stored. When this process ends, the process moves to a step S44.

  Such a jackpot determination random number is an example of information for determining whether or not to shift to a special game state in which a predetermined game value can be given to the player. Then, the main CPU 101 that performs the processing of step S34 or step S43 functions as an information acquisition unit that acquires information for determining whether or not to shift to a special gaming state in which a predetermined gaming value can be given to the player. . Further, the main CPU 101 obtains a jackpot determination random number value on condition that a detection signal is received from the first start opening winning ball sensor 116a or the second starting opening winning ball sensor 116b. That is, the main CPU 101 as information acquisition means acquires information based on the establishment of a predetermined condition. Further, the main RAM 103 that stores the jackpot determination random number value as information during the change of the special symbol, when the information is acquired by the information acquisition unit during the change display of the identification symbol in the display unit, It functions as information storage means for storing.

  In step S44, a special symbol determination process is performed. In this process, the main CPU 101 refers to the jackpot random number determination table (see FIG. 20) and the jackpot symbol random number determination table (see FIG. 21) based on the jackpot determination random number value and the jackpot symbol random number value extracted in step S43. Then, the special symbol to be stopped and displayed on the special symbol display device 421 is determined, and data indicating the special symbol is stored in a predetermined area of the main RAM 103.

  Specifically, the main CPU 101 refers to the big hit random number determination table (second start port) shown in FIG. 20B and the big hit symbol random number determination table (second start port) shown in FIG. The symbol designation command associated with the special symbol to be stopped and displayed on the special symbol display device 421 is determined on the basis of the random number for jackpot determination extracted in (1). Specifically, the main CPU 101 determines the jackpot extracted in step S43 when the extracted jackpot determination random number value is associated with the jackpot determination value data in the jackpot random number determination table (second start port). Based on the symbol random number value, the symbol designation command “z0” or “z4” is selected with reference to the jackpot symbol random number determination table (second start port). Further, the main CPU 101 selects the symbol designation command “z5” when the extracted jackpot determination random number value is associated with the loss determination value data in the jackpot random number determination table (second start port). . If this process ends, the process moves to a step S45.

  In step S45, jackpot determination processing is performed. In this process, the main CPU 101 refers to the jackpot random number determination table (second start port) shown in FIG. 20B, and the jackpot determination random number extracted in step S43 is associated with the jackpot determination value data. Judgment is made. If this process ends, the process moves to a step S46.

  In step S46, a variation pattern determination process is performed. In this process, the main CPU 101 extracts a variation pattern random number value, and determines a special symbol variation pattern based on the variation pattern random value, the special symbol determined in step S44, and the result of the jackpot determination process in step S45. The fluctuation pattern is determined with reference to the fluctuation pattern determination table (see FIG. 22) for storing the data, and stored in a predetermined area of the main RAM 103. The main CPU 101 determines the variation display mode of the special symbol in the special symbol display device 421 based on such data indicating the variation pattern.

  Further, the main CPU 101 supplies data indicating the determined variation pattern to the special symbol display device 421. The special symbol display device 421 variably displays the special symbol for the variation time defined in the variation pattern determination table (see FIG. 22) based on the data indicating the variation pattern, and is associated with the symbol designation command. Stop display. Data indicating the variation pattern is supplied from the main CPU 101 of the main control circuit 100 to the sub CPU 201 of the sub control circuit 200 as a variation pattern designation command. The data indicating the variation pattern includes pseudo continuous designation data for designating execution of the pseudo continuous effect. Whether or not to execute the pseudo-continuous effect is determined by random number lottery or the like. The sub CPU 201 of the sub control circuit 200 executes an effect display according to the received variation pattern designation command. If this process ends, the process moves to a step S47.

  The main CPU 101 that executes the process of step S37 or step S46 determines the variation pattern that is the information indicating the variation time of the identification symbol based on the information (random number for jackpot determination) acquired as the information acquisition unit. Functions as time determination means.

  In step S47, a second start opening winning hold number increase command set process is performed. In this process, the main CPU 101 sets a reserved number increase command for driving the second special symbol hold display device 423b (see FIG. 4) in accordance with the process of adding “1” to the hold number value in step S42. Processing to be stored in the RAM 103 is performed. The main CPU 101 supplies this reserved number increase command to the second special symbol hold display device 423b. The second special symbol hold display device 423b turns on the display lamp based on the supplied hold number increase command. When this process is finished, this subroutine is finished.

  As described above, the main CPU 101 determines a special symbol and a variation pattern for each winning prize at the first start port 414a or the second start port 414b (see FIG. 4). The main CPU 101 also displays the first special symbol hold as a hold once even if the number of holds is “0” and the special symbol is not variably displayed, even if the first start port 414a or the second start port 414b is won. The device 423a or the second special symbol hold display device 423b is turned on and then immediately turned off, and the special symbol variation display is started. Note that the main CPU 101 does not turn on the first special symbol hold display device 423a or the second special symbol hold display device 423b as a hold once and determines that the hold number is not “0” as an internal process. The symbols may be displayed in a variable manner.

[Main control main processing]
Next, main control main processing executed by the main CPU 101 will be described with reference to FIGS. 9, 11, 12, 13, 14, and 15. As shown in FIG. 9, initial setting is performed in step S50. In this process, the main CPU 101 reads a startup program from the main ROM 102 in response to power-on, initializes a flag stored in the main RAM 103, or returns to a state before power-off. If this process ends, the process moves to a step S51.

  In step S51, initial value random number update processing is performed. In this process, the main CPU 101 performs a process of updating the initial value random number counter. When this process ends, the process moves to a step S52.

  In step S52, a special symbol control process is performed. As will be described in detail later, in this process, the main CPU 101 determines the jackpot random number determination table (first start port) shown in FIG. 20A or FIG. 20 based on the jackpot determination random number extracted in step S34 or S43. With reference to the big hit random number determination table (second start port) shown in (b), it is determined whether or not a special symbol lottery (big hit or small win) has been won, and the result of determination is stored in the main RAM 103. . When this process ends, the process moves to a step S53. Based on the information acquired by the information acquisition means, the main CPU 101 that executes the processing of step S52 as described above is a gaming state that is advantageous to the player as a gaming state that can be controlled after the special gaming state and the special gaming state have ended. It functions as a gaming state control means capable of controlling a certain first gaming state or a second gaming state that is a disadvantageous gaming state over the first gaming state.

  In step S53, normal symbol control processing is performed. As will be described in detail later, in this process, the main CPU 101 extracts a random number value in accordance with a detection signal from the first sphere passage detection sensor 115a or the second sphere passage detection sensor 115b, and is stored in the main ROM 102. With reference to the symbol winning table, it is determined whether or not the normal symbol lottery has been won, and the result of determination is stored in the main RAM 103. When the normal symbol lottery is won, the blade member of the ordinary electric accessory 415 is in an open state, and the game ball can easily enter the second start port 414b (see FIG. 4). If this process ends, the process moves to a step S54.

  In step S54, a symbol display device control process is performed. In this process, the main CPU 101 determines the special symbol display device 421 and the normal symbol display device 424 according to the result of the special symbol control process stored in the main RAM 103 in step S52 and step S53 and the result of the normal symbol control process. The control signal for driving is stored in the main RAM 103. The main CPU 101 transmits this control signal to the special symbol display device 421 or the normal symbol display device 424. The special symbol display device 421 displays the special symbol in a variable manner and a stop manner based on the received control signal. The normal symbol display device 424 displays the normal symbol in a variable manner and stops based on the received control signal. When this process ends, the process moves to a step S55.

  In step S55, game information data generation processing is performed. In this process, the main CPU 101 generates game information data to be transmitted to the sub-control circuit 200, the payout / launch control circuit 300, the hall computer, etc., and stores it in the main RAM 103. When this process ends, the process moves to a step S56.

  In step S56, storage / game state data generation processing is performed. In this process, the main CPU 101 generates storage / game state data to be transmitted to the sub-control circuit 200 according to the probability change flag and the time reduction flag, and stores it in the main RAM 103. The stored / game state data is transmitted to the sub-control circuit 200 as a game state command. When this process ends, the process moves to a step S51.

[Special symbol control processing]
The subroutine (special symbol control process) executed in step S52 of FIG. 9 will be described with reference to FIG. In FIG. 10, numerical values drawn on the sides of step S <b> 60 to step S <b> 69 indicate control state flags corresponding to those steps, and are stored in a storage area that functions as a control state flag in the main RAM 103. The main CPU 101 executes one step corresponding to the numerical value of the control state flag stored in the main RAM 103, and advances the special symbol game.

  In step S60, a process for loading a control state flag is performed. In this process, the main CPU 101 reads a control state flag stored in the main RAM 103. If this process ends, the process moves to a step S61.

  In step S61 to step S69 described later, the main CPU 101 determines whether or not to execute various processes in each step based on the value of the control state flag, as will be described later. This control state flag indicates the state of the special symbol game, and enables one of the processes from step S61 to step S69. In addition, the main CPU 101 executes processing in each step at a predetermined timing determined according to a waiting time timer set for each step. Before reaching the predetermined timing, the process ends without executing the process in each step, and another subroutine is executed.

  In step S61, a special symbol memory check process is performed. Although details of this process will be described later, in this process, when the control state flag is a value (00) indicating a special symbol storage check, the main CPU 101 checks the number of reserved special symbols. If this process ends, the process moves to a step S62.

  In step S62, a special symbol variation time management process is performed. In this process, the main CPU 101 sets the control state flag to a value (01) indicating special symbol variation time management, and when the variation time has elapsed, sets the value (02) indicating special symbol display time management to the control state flag. The symbol stop command is stored in the main RAM 103, and the waiting time after determination (for example, 1 second) is set in the waiting time timer. That is, it is set to execute the process of step S63 after the waiting time after determination has elapsed. The symbol stop command is transmitted to the sub control circuit 200 by the main CPU 101 of the main control circuit 100, so that the sub CPU 201 of the sub control circuit 200 recognizes the symbol stop. If this process ends, the process moves to a step S63.

  In step S63, a special symbol display time management process is performed. Although details of this process will be described later, in this process, the main CPU 101 determines that the control state flag is a value (02) indicating special symbol display time management, and if the waiting time after determination has passed, Judgment whether or not. In the case of winning, the main CPU 101 sets a value (03) indicating the big hit start interval management in the control state flag, and sets the time corresponding to the big hit start interval in the waiting time timer. That is, after the time corresponding to the big hit start interval elapses, the process of step S64 is set to be executed. On the other hand, the main CPU 101 sets a value (08) indicating the end of the special symbol game when it is not a win. That is, it sets so that the process of step S69 may be performed. If this process ends, the process moves to a step S64 or a step S69.

  In step S64, a big hit start interval management process is performed. In this process, the main CPU 101 has a value (03) indicating that the control status flag indicates the jackpot start interval management, and when the time corresponding to the jackpot start interval has elapsed, a value (04) indicating that the big prize opening is open. Is set in the control status flag. That is, it sets so that the process of step S65 may be performed. If this process ends, the process moves to a step S65.

  In step S65, a special winning opening opening process is performed. In this process, the main CPU 101 uses the upper limit opening time (for example, about 30 seconds) of the first big prize opening 418a (see FIG. 4) or the second big prize opening 418b (see FIG. 4) as the big prize opening time timer. The main RAM 103 stores data for opening the first big prize opening 418 a or the second big prize opening 418 b read from the main ROM 102. The main CPU 101 then opens the first big prize opening 418a (see FIG. 4) or the second big prize opening 418b (see FIG. 4) stored in the main RAM 103 in the process of step S14 in FIG. And a solenoid power source for opening the first grand prize opening 418a or the second big prize opening 418b, the first big prize opening solenoid 112a (see FIG. 5) for driving the shutter 417a of the first big prize opening 418a or It supplies to the 2nd big winning opening solenoid 112b (refer FIG. 5) which drives the shutter 417b of the 2nd big winning opening 418b. Then, the main CPU 101 sets a value (05) indicating monitoring of the winning ball remaining ball in the control state flag after the upper open limit time has elapsed. That is, it sets so that the process of step S66 may be performed. If this process ends, the process moves to a step S66.

  In step S66, a special winning opening residual ball monitoring process is performed. In this process, the main CPU 101 indicates that the control status flag is a value (05) indicating monitoring of the winning ball remaining ball in the winning game mouth, and the winning game mouth winning counter is “7” or more when the winning ball remaining ball monitoring time has elapsed. It is determined whether or not the condition that the special winning opening opening number counter is equal to or greater than a predetermined number (the final round) is satisfied. When any of the conditions is satisfied, the main CPU 101 sets a value (07) indicating the big hit game end interval in the control state flag. On the other hand, when neither of the conditions is satisfied, the main CPU 101 sets a value (06) indicating the waiting time management before reopening the big winning opening to the control state flag. If this process ends, the process moves to a step S67 or a step S68.

  In step S67, a waiting time management process before reopening the big winning opening is performed. In this process, the main CPU 101 sets the special prize opening number counter when the control status flag is a value (06) indicating the waiting time management before the big prize opening reopening and the time corresponding to the interval between rounds has elapsed. The memory is updated so that “1” is increased. The main CPU 101 sets a value (04) indicating that the special winning opening is open in the control state flag. That is, it sets so that the process of step S65 may be performed. If this process ends, the process moves to a step S65.

  In step S68, jackpot end interval processing is performed. Details of this process will be described later. In this process, the main CPU 101 determines that the control state flag is a value (07) indicating the jackpot end interval, and the special symbol game when the time corresponding to the jackpot end interval has elapsed. A value (08) indicating the end is set in the control state flag. That is, it is set to execute the process of step S69. If this process ends, the process moves to a step S69.

  In step S69, a special symbol game end process is performed. In this process, the main CPU 101 sets a value (00) indicating a special symbol storage check when the control state flag is a value (08) indicating the end of the special symbol game. That is, it sets so that the process of step S61 may be performed. When this process is finished, this subroutine is finished.

  Thus, the main CPU 101 executes the special symbol game by setting the control state flag. Specifically, the main CPU 101 sets the control status flags to (00), (01), (02), and (08) when the hit determination result is lost when the game is not in the big hit or small hit gaming state. By setting in order, the processing of step S61, step S62, step S63, and step S69 shown in FIG. 10 is executed at a predetermined timing. In addition, when the main CPU 101 is not in the big hit or small hit gaming state and the result of the hit determination is a big hit or small hit, the control state flag is set to (00), (01), (02), (03). By setting in order, the processing of step S61, step S62, step S63, and step S64 shown in FIG. 10 is executed at a predetermined timing, and control to the big hit or small hit gaming state is executed. Furthermore, when the control to the big hit or the small hit game state is executed, the main CPU 101 sets the control state flags in the order of (04), (05), (06), as shown in FIG. The processing of step S65, step S66, and step S67 is executed at a predetermined timing, and a big hit or small hit game is executed. When the big hit or small hit game ending conditions are satisfied, the processing in steps S68 and S69 shown in FIG. 10 is executed at a predetermined timing by sequentially setting (07) and (08). End the big hit or small hit game.

[Special symbol memory check processing]
The subroutine (special symbol storage check process) executed in step S61 in FIG. 10 will be described with reference to FIG. In step S70, it is determined whether or not the control state flag is a value (00) indicating a special symbol storage check. In this process, when the main CPU 101 determines that the control state flag is the value (00) indicating the special symbol storage check, the process proceeds to step S71. On the other hand, when the main CPU 101 determines that the control state flag is not the value (00) indicating the special symbol storage check, the main CPU 101 ends the present subroutine.

  In step S71, a process of determining whether or not the number of reserved second start opening winnings is “0” is performed. In this process, the main CPU 101 determines the presence / absence of data in the second special symbol start storage area (0) to the second special symbol start storage area (4) of the main RAM 103. In the main CPU 101, the start memory corresponding to the second special symbol is “0”, that is, no data is stored in the second special symbol start storage area (0) to the second special symbol start storage area (4). If it is determined, the process proceeds to step S77. On the other hand, in the main CPU 101, the start memory corresponding to the second special symbol is not “0”, that is, data is stored in the second special symbol start storage area (0) to the second special symbol start storage area (4). If it is determined that there is, the process proceeds to step S72.

  In step S72, a process of subtracting “1” from the second starting stored number is performed. In this process, the main CPU 101 performs a process of clearing data in the second special symbol start storage area (0) of the main RAM 103. If this process ends, the process moves to a step S73.

  In step S73, a special symbol storage area transfer process based on the second start opening winning is performed. In this process, the main CPU 101 uses the second special symbol start storage area (0) to the second special symbol start storage area (0) to the second special symbol start storage area (1) to the second special symbol start storage area (4) of the main RAM 103, respectively. 2. Shift (store) the special symbol start storage area (3). If this process ends, the process moves to a step S74.

  In step S74, a process of setting a value (01) indicating special symbol variation time management to the control state flag is performed. In this process, the main CPU 101 performs a process of setting a value (01) indicating special symbol variation time management to the control state flag. If this process ends, the process moves to a step S75. Further, the main CPU 101 generates a derived symbol designation command for determining a derived symbol corresponding to the special symbol that is stopped and displayed on the special symbol display device 421 by the sub CPU 201, which will be described later, and the main RAM 103 Is stored in a predetermined area. The main CPU 101 outputs this derived symbol designation command to the sub-control circuit 200 in step S14 shown in FIG. The sub CPU 201 of the sub control circuit 200 starts to display the derived symbol variation display based on the received derived symbol designation command.

  In step S75, a waiting time setting process is performed. In this process, the main CPU 101 performs a process of setting a variation time corresponding to the variation pattern of the special symbol determined in step S37 or step S46 shown in FIG. If this process ends, the process moves to a step S76.

  In step S76, processing for clearing the storage area used for the current variation is performed. In this process, the main CPU 101 performs a process of clearing the storage area of the main RAM 103 used for the current variable display. When this process is finished, this subroutine is finished.

  In step S77, a process is performed to determine whether or not the number of first start opening prizes held is "0". In this process, the main CPU 101 determines the presence / absence of data in the first special symbol start storage area (0) to the first special symbol start storage area (4) of the main RAM 103. The main CPU 101 determines that the start memory corresponding to the first special symbol is 0, that is, no data is stored in the first special symbol start storage area (0) to the first special symbol start storage area (4). If so, the process moves to step S80. On the other hand, when the start memory corresponding to the first special symbol is not 0, the main CPU 101 stores data in the first special symbol start storage area (0) to the first special symbol start storage area (4). If so, the process moves to step S78. The main CPU 101 performs the process of step S77 after the process of step S71. That is, the main CPU 101 preferentially digests the second start opening prize.

  In step S78, a process of subtracting "1" from the first starting stored number is performed. In this process, the main CPU 101 performs a process of clearing data in the first special symbol start storage area (0) of the main RAM 103. If this process ends, the process moves to a step S79.

  In step S79, a special symbol storage area transfer process based on the first start opening prize is performed. In this process, the main CPU 101 uses the first special symbol start storage area (0) to the first special symbol start storage area (0) to the first special symbol start storage area (1) to the first special symbol start storage area (4) of the main RAM 103, respectively. 1 A special symbol start storage area (3) is shifted (stored). If this process ends, the process moves to a step S74.

  In step S80, a demonstration display process is performed. In this process, the main CPU 101 performs a process of setting a demonstration display permission value in the main RAM 103. In addition, the main CPU 101 determines that the state in which the special symbol game start memory (the first special symbol start memory area or the second special symbol start memory area in which the random number value for hit determination is stored) is 0 for a predetermined time (for example, , 30 seconds), the value that permits execution of the demo display is set as the demo display permission value. When the demonstration display permission value is a predetermined value, the main CPU 101 sets a demonstration display command and supplies it to the sub control circuit 200. The sub-control circuit 200 performs a demonstration display on the liquid crystal display device 50 based on this demonstration display command. When this process is finished, this subroutine is finished.

[Special symbol display time management process]
The subroutine (special symbol display time management process) executed in step S63 in FIG. 10 will be described with reference to FIGS. As shown in FIG. 12, in step S90, it is determined whether or not the control state flag is a value (02) indicating special symbol display time management. In this process, the main CPU 101 performs a process of determining whether or not the control state flag is a value (02) indicating the special symbol display time management process. If the main CPU 101 determines that the control state flag is a value (02) indicating the special symbol display time management process, the main CPU 101 moves the process to step S91, and the control state flag is a value indicating the special symbol display time management process ( If it is not (02), this subroutine is terminated.

  In step S91, it is determined whether or not the waiting time is “0”. In this process, the main CPU 101 determines whether or not the value of the waiting time timer corresponding to the special symbol display management process is “0”. When determining that the value of the waiting time timer is “0”, the main CPU 101 moves the process to step S92, and when determining that the value of the waiting time timer is not “0”, the main CPU 101 ends the present subroutine.

  In step S92, a process for determining whether or not a big hit is performed. In this process, the main CPU 101 uses the probability variation flag stored in the main RAM 103 and the jackpot random number determination table (first start port) shown in FIG. 20A or the jackpot random number determination table (second block) shown in FIG. The big hit determination random number value stored in the first special symbol start storage area (0) or the second special symbol start storage area (0) of the main RAM 103 is associated with the big hit determination value data. It is determined whether or not it is a value obtained (whether or not it is a big hit). If the main CPU 101 determines that it is a big hit, it moves the process to step S98 shown in FIG. 13, and if it determines that it is not a big hit, moves the process to step S93. The main CPU 101 that executes the process of step S92 performs a jackpot determination unit that determines whether or not to shift to the special gaming state according to the variation of the identification symbol based on the information stored in the information storage unit. Function as. In this process, the main CPU 101 also performs a process of determining whether or not the game is a small hit. Specifically, the main CPU 101 refers to the probability variation flag stored in the main RAM 103 and the big hit random number determination table (first start port) shown in FIG. It is determined whether or not the big hit determination random number stored in (0) is a value associated with the small hit determination value data (small hit). If the main CPU 101 determines that it is a small hit, the first big prize opening 418a or the second big prize opening 418b is opened for a certain period of time, and if it is determined that it is not a small hit, the process proceeds to step S93. . The main CPU 101 determines that it is a small hit, and when the first big prize opening 418a and the second big prize opening 418b are opened for a certain period and then closed (when the big prize opening time as a small hit has elapsed). Is controlled so that the gaming state after the end of the small hit gaming state does not become a more advantageous gaming state than the gaming state at the time of winning the small hit. It should be noted that the big winning opening opening time as a small hit is the total opening time that is the total of the opening times when the first big winning opening 418a and the second big winning opening 418b are repeatedly opened and closed.

  In step S93, a process of setting a value (08) indicating the end of the special symbol game to the control state flag is performed. In this process, the main CPU 101 performs a process of setting a value (08) indicating the end of the special symbol game in the control state flag. If this process ends, the process moves to a step S94.

  In step S94, a process for determining whether or not the short-time state variation number counter is “0” is performed. In this process, the main CPU 101 determines whether or not the value of the time-short state change frequency counter in the main RAM 103 is “0”. Here, the time-short state change frequency counter indicates the number of times the special symbol is changed and stopped in the time-short state. If the main CPU 101 determines that the value of the short-time state variation number counter is “0”, the main CPU 101 ends this subroutine. If the main CPU 101 determines that the value of the short-time state variation number counter is not “0”, The process moves to S95.

  In step S95, a process of subtracting “1” from the short-time state fluctuation count counter is performed. In this process, the main CPU 101 performs a process of subtracting “1” from the short-time state fluctuation frequency counter of the main RAM 103. If this process ends, the process moves to a step S96.

  In step S96, it is determined whether or not the time state change frequency counter is “0”. In this process, the main CPU 101 determines whether or not the value of the time-short state change frequency counter in the main RAM 103 is “0”. If the main CPU 101 determines that the value of the short-time state variation number counter is “0”, the main CPU 101 shifts the process to step S97, and determines that the value of the short-time state variation number counter is not “0”. This subroutine ends.

  In step S97, processing for setting the time reduction flag to “0” is performed. In this process, the main CPU 101 performs a process of setting “0” to the time reduction flag stored in the main RAM 103. Here, the time reduction flag is stored in the main RAM 103 and indicates whether or not the time reduction state is selected as the gaming state after the big hit, and when the value is “0”, it is not the time reduction state. (Non-time-short state) is shown, and when the value is “1”, the time-short state is indicated. In the process of step S56 shown in FIG. 9, the main CPU 101 generates game state data to be transmitted to the sub control circuit 200 according to the value of the time reduction flag. When this process is finished, this subroutine is finished.

  As shown in FIG. 13, in step S98, a big hit mode determination process is performed. In this process, the main CPU 101 determines the big hit mode based on the symbol designation command determined in step S35 or step S44 shown in FIG. Specifically, when the symbol designation command is “z0”, “z1”, “z2”, and “z3”, the main CPU 101 determines a big hit mode with the number of rounds being “10”, and the symbol designation command is “ In the case of z4 ”, the big hit mode in which the number of rounds is“ 16 ”is determined. The main CPU 101 determines the small hit mode when the symbol designation command is “z11”. If this process ends, the process moves to a step S99.

  In step S99, a big hit flag set process is performed. In this process, the main CPU 101 sets a big hit flag in the main RAM 103 when it is determined that the big win is obtained in the process of step S92 shown in FIG. If this process ends, the process moves to a step S100.

  In step S100, a special winning opening opening number counter clear process, a short time state change number counter clear process, a short time flag clear process, and a probability change flag clear process are performed. In this process, the main CPU 101 clears the special winning opening opening number counter and the short time state fluctuation number counter stored in the main RAM 103. Further, the main CPU 101 stores the value of the time reduction flag in the main RAM 103 as the winning time reduction flag, and then performs a process of setting “0” to the time reduction flag. Further, the main CPU 101 stores the value of the probability variation flag in the main RAM 103 as the winning probability variation flag, and then performs a process of setting “0” to the probability variation flag. If this process ends, the process moves to a step S101.

  In step S101, a process of setting a value (03) indicating the big hit start interval management to the control state flag is performed. In this process, the main CPU 101 performs a process of setting a value (03) indicating the big hit start interval management in the control state flag. If this process ends, the process moves to a step S102.

  In step S102, a waiting time (5000 ms) is set as a big hit start interval time. In this process, when the main CPU 101 determines that the big hit is made in step S92 shown in FIG. 12, the main CPU 101 performs a process of setting the value of the waiting time timer (5000 ms) in the main RAM 103 as the big hit start interval time. . If this process ends, the process moves to a step S103.

  In step S103, jackpot start command set processing is performed. In this process, when the main CPU 101 determines that the big hit is made in the process of step S92 shown in FIG. 12, the main CPU 101 performs a process of setting a big hit start command in the main RAM 103. If this process ends, the process moves to a step S104. Here, the big hit start command set in the process of this step and the small hit start command set when it is determined that the big hit is determined in the process of step S99, are sent from the main CPU 101 of the main control circuit 100 to the sub control circuit 200. By being supplied to the sub CPU 201, the sub control circuit 200 recognizes the big hit or the small hit start.

  In step S104, a special winning opening opening frequency data set process is performed. In this process, the main CPU 101 sets the big winning opening opening number data according to the big hit mode or the small hit mode determined in the big hit mode determining process in step S98. Specifically, the main CPU 101 sets “10” as the upper limit value in the big winning opening opening number counter of the main RAM 103 when the big hit mode with the number of rounds “10” is determined in the big hit mode determination process. To do. Further, when the main CPU 101 determines the big hit mode with the number of rounds “16” in the big hit mode determination process, the main CPU 101 sets “16” as the upper limit value in the big winning opening opening number counter of the main RAM 103. Also, when the main CPU 101 determines the small hit mode in the big hit mode determination process, the main CPU 101 sets “1” as the upper limit value to the big winning opening opening number counter of the main RAM 103. Note that the count value of the number-of-releases counter is synonymous with the number of rounds. If this process ends, the process moves to a step S105.

  In step S105, a round number display LED pattern flag setting process is performed. In this processing, the main CPU 101 sets a round number display LED pattern flag for performing display control of the round number display device 422 in the main RAM 103. When this process is finished, this subroutine is finished.

[Big hit end interval processing]
The subroutine (big hit end interval process) executed in step S68 of FIG. 10 will be described with reference to FIG. In step S110, it is determined whether or not the control state flag is a value (07) indicating a big hit end interval. In this process, the main CPU 101 performs a process of determining whether or not the control state flag of the main RAM 103 is a value (07) indicating the big hit end interval process. If the main CPU 101 determines that the control state flag is a value (07) indicating the big hit end interval process, the main CPU 101 moves the process to step S111, and the control state flag is not a value (07) indicating the big hit end interval process. If so, this subroutine is terminated.

  In step S111, a process for determining whether or not the waiting time is “0” is performed. In this process, the main CPU 101 determines whether or not the value of the waiting time timer corresponding to the jackpot end interval process is “0”. When the main CPU 101 determines that the value of the waiting time timer is “0”, the main CPU 101 proceeds to step S112, and when it determines that the value of the waiting time timer is not “0”, the main CPU 101 ends this subroutine. To do.

  In step S112, a special winning opening opening number display LED pattern flag clear process is performed. In this processing, the main CPU 101 performs processing for clearing the special winning opening opening number display LED pattern flag stored in the main RAM 103. If this process ends, the process moves to a step S113.

  In step S113, a round number distribution flag clear process is performed. In this process, the main CPU 101 performs a process of clearing the round number distribution flag stored in the main RAM 103. If this process ends, the process moves to a step S114.

  In step S114, a process of setting a value (08) indicating the end of the special symbol game to the control state flag is performed. In this process, the main CPU 101 performs a process of setting a value (08) indicating the end of the special symbol game in the control state flag. If this process ends, the process moves to a step S115.

  In step S115, a big hit flag clear process is performed. In this process, the main CPU 101 performs a process of clearing the jackpot flag stored in the main RAM 103 when the jackpot flag is set in the process of step S99 shown in FIG. If this process ends, the process moves to a step S116.

  In step S116, probability variation flag setting processing is performed. In this process, the main CPU 101, based on the symbol designation command determined in step S35 or S44 shown in FIG. 8 and the winning time short flag and the winning time certainty change flag stored in the main RAM 103 in step S100 shown in FIG. With reference to the jackpot type determination table shown in FIG. 23, processing for setting a probability variation flag in the main RAM 103 is performed. If this process ends, the process moves to a step S117.

[Big hit type determination table]
Here, the jackpot type determination table will be described with reference to FIG. The big hit type determination table is stored in the main ROM 102, and the symbol designation command ("z0", "z1", "z2", "z3", "z4") with the big hit type is selected as the winning type for a plurality of types of variation patterns. The time reduction flag, the time reduction count, the probability variation flag, the probability variation count, and the round count are associated with each other.

  The symbol designation command in the jackpot type determination table is a value corresponding to the symbol designation command in the jackpot symbol random number determination table (see FIG. 21). Further, the number of time reductions in the jackpot type determination table indicates an upper limit value of the number of times the special symbol fluctuates in the time reduction state started after the end of the jackpot gaming state. In the present embodiment, the time saving state is ended when a big win is won or when there is a change in the special symbol for the number of time reductions shown in the big hit type determination table. That is, the state shifts from the time-saving state to the non-time-saving state. In addition, the number of probability changes in the jackpot type determination table indicates the upper limit value of the number of times the special symbol fluctuates in the probability variation state started after the end of the jackpot gaming state. In the present embodiment, the probability variation state ends when a big win is won or when there is a change in the special symbol for the number of probability variations shown in the big hit type determination table. That is, the state changes from the probability variation state to the non-probability variation state.

  The big hit type determination table stores four tables in the main ROM 102 according to the values of the winning time short flag and the winning time probability variable flag. Specifically, in the jackpot type determination table shown in FIG. 23A, the value of the winning time reduction flag is “0” and the winning time probability variable flag is “0”, that is, the non-time reduction state and When a big hit is made in the non-probable change state, the main CPU 101 refers to it. Further, in the jackpot type determination table shown in FIG. 23 (b), when the value of the winning time short flag is “1” and the winning time probability variable flag is “0”, that is, in the short time state and the non-probable state. When the big hit is sometimes made, it is referred to by the main CPU 101. Further, in the jackpot type determination table shown in FIG. 23C, when the value of the winning time short flag is “0” and the winning time probability variable flag is “1”, that is, in the non-time short state and the probability varying state. When the big hit is sometimes made, it is referred to by the main CPU 101. Further, in the big hit type determination table shown in FIG. 23D, when the value of the winning time short flag is “1” and the winning time probability changing flag is “1”, that is, in the time shortening state and the probability changing state. When it is a big hit, it is referred to by the main CPU 101.

  The big hit types in this embodiment include big hit 1, big hit 2, big hit 3, big hit 4, and big hit 5. The jackpot 1 is a jackpot where the gaming state after the jackpot gaming state ends becomes a non-time-short state and a non-probability changing state. The jackpot 2 is a jackpot in which the gaming state after the jackpot gaming state ends becomes a non-time-short state and a probability variation state (so-called latent probability variation). The jackpot 3 is a jackpot in which the gaming state after the jackpot gaming state ends is a short-time state and a probable change state of less than 200 times. The big hit 4 is a big hit where the gaming state after the big hit gaming state is a short-time state and a probable change state of 200 time-saving times. The jackpot 5 is a jackpot where the gaming state after the jackpot gaming state ends is a short time state and a non-changeable state.

  In the jackpot type determination table shown in FIG. 23 (a) that is referred to when the jackpot is in the non-short-time state or the non-probability change state, the jackpot 1 is associated with the symbol designation command “z0” and the jackpot is hit with “z1”. 2, jackpot 3 is associated with “z2” and “z3”, and jackpot 4 is associated with “z4”. Also, in the jackpot type determination table shown in FIG. 23 (b) which is referred to when the jackpot is in the short-time state or the uncertain change state, the jackpot 1 is associated with the symbol designation command “z0” and “z1” Big hit 2 is associated, "z2" and "z3" are associated with big hit 3, and "z4" is associated with big hit 4. Further, in the jackpot type determination table shown in FIG. 23 (c) which is referred to when the jackpot is in the non-short-time state and the probability variation state, the jackpot 1 is associated with the symbol designation command “z0”, and “z1” to Big hit 3 is associated with “z3”, and big hit 4 is associated with “z4”. Further, in the jackpot type determination table shown in FIG. 23 (d) that is referred to when the jackpot is in the short-time state or the probability variation state, the jackpot 5 is associated with the symbol designation command “z0” and the jackpot is hit with “z1”. 3 is associated, and the big hit 4 is associated with “z2” to “z4”.

  Returning to FIG. 14, specifically, in step S116, the main CPU 101 determines that the big hit corresponding to the winning time short flag and the winning time certain change flag in the big hit type determination table shown in FIGS. 23 (a) to 23 (d). With reference to the type determination table, the value of the probability variation flag associated with the symbol designation command is read and stored in the main RAM 103. Also, the main CPU 101 refers to the big hit type determination table corresponding to the winning time short flag and the winning time certain change flag among the big hit type determination tables shown in FIGS. A big hit type command indicating the big hit type (big hit 1, big hit 2, big hit 3, big hit 4 or big hit 5) is generated and stored in the main RAM 103.

  In step S117, a time reduction flag set process is performed. In this process, the main CPU 101, based on the symbol designation command determined in step S35 or S44 shown in FIG. 8 and the winning time short flag and the winning time certainty change flag stored in the main RAM 103 in step S100 shown in FIG. With reference to the jackpot type determination table shown in FIG. 23, processing for setting a time reduction flag in the main RAM 103 is performed. If this process ends, the process moves to a step S118. Specifically, the main CPU 101 refers to the jackpot type determination table according to the winning time short flag and the winning time probability change flag among the big hit type determination tables shown in FIGS. The time flag value associated with is read out and stored in the main RAM 103.

  In step S118, processing for determining whether or not the probability variation flag is “1” is performed. In this processing, the main CPU 101 performs processing for determining whether or not the value of the probability variation flag in the main RAM 103 is “1”. If the main CPU 101 determines that the value of the probability variation flag is “1”, the process proceeds to step S119. If the main CPU 101 determines that the value of the probability variation flag is not “1”, the process proceeds to step S120. .

  In step S119, a process of setting the probability variation number in the probability variation state variation frequency counter is performed. In this process, the main CPU 101, based on the symbol designation command determined in step S35 or S44 shown in FIG. 8 and the winning time short flag and the winning time certainty change flag stored in the main RAM 103 in step S100 shown in FIG. With reference to the jackpot type determination table shown in FIG. 23, processing for setting the probability variation number in the probability variation state variation frequency counter of the main RAM 103 is performed. If this process ends, the process moves to a step S120. Specifically, the main CPU 101 refers to the jackpot type determination table according to the winning time short flag and the winning time probability change flag among the big hit type determination tables shown in FIGS. The value of the probability variation number associated with is read out and stored in the main RAM 103.

  In step S120, it is determined whether or not the time reduction flag is “1”. In this processing, the main CPU 101 performs processing for determining whether or not the value of the time reduction flag in the main RAM 103 is “1”. When the main CPU 101 determines that the value of the time reduction flag is “1”, the main CPU 101 shifts the process to step S121, and when it determines that the value of the time reduction flag is not “1”, the main CPU 101 ends the present subroutine.

  In step S121, processing for setting the number of time reductions in the time reduction state variation number counter is performed. In this process, the main CPU 101, based on the symbol designation command determined in step S35 or S44 shown in FIG. 8 and the winning time short flag and the winning time certainty change flag stored in the main RAM 103 in step S100 shown in FIG. With reference to the big hit type determination table shown in FIG. When this process is finished, this subroutine is finished. Specifically, the main CPU 101 refers to the jackpot type determination table according to the winning time short flag and the winning time probability change flag among the big hit type determination tables shown in FIGS. The value of the short time count associated with is read out and stored in the main RAM 103.

[Normal symbol control processing]
A subroutine (ordinary symbol control process) executed in step S53 of FIG. 9 will be described with reference to FIG. In FIG. 15, the numerical values drawn from step S <b> 130 to step S <b> 135 indicate normal symbol control state flags corresponding to those steps, and are stored in a storage area functioning as a normal symbol control state flag in the main RAM 103. ing. The main CPU 101 executes one step corresponding to the numerical value of the normal symbol control state flag stored in the main RAM 103, and the normal symbol game proceeds.

  In step S130, the normal symbol control state flag is loaded. In this process, the main CPU 101 reads the normal symbol control state flag stored in the main RAM 103. If this process ends, the process moves to a step S131.

  In steps S131 to S135, which will be described later, the main CPU 101 determines whether or not to execute various processes in each step based on the value of the normal symbol control state flag, as will be described later. The normal symbol control state flag indicates the game state of the normal symbol game, and allows one of the processes in steps S131 to S135 to be executed. In addition, the main CPU 101 executes processing in each step at a predetermined timing determined according to a waiting time timer set for each step. Before reaching the predetermined timing, the process ends without executing the process in each step, and another subroutine is executed.

  In step S131, a normal symbol storage check process is performed. In this process, when the normal symbol control state flag is a value (00) indicating the normal symbol storage check, the main CPU 101 sets the value of the normal symbol hold storage number counter (hold number) stored in the main RAM 103 to “ It is determined whether or not it is 0 ". When the value of the normal symbol reserved memory number counter is “0”, the main CPU 101 sets a value (04) indicating the normal symbol game end process in the normal symbol control state flag. On the other hand, when the value of the normal symbol reserved memory number counter is not “0”, the main CPU 101 sets a value (01) indicating the normal symbol variation time monitoring process in the normal symbol control state flag, Set the fluctuation time to the waiting time timer. If this process ends, the process moves to step S135 or step S132.

  In step S132, normal symbol variation time monitoring processing is performed. In this process, the main CPU 101 sets the normal symbol control state flag to a value (01) indicating normal symbol variation time monitoring, and when the variation time has elapsed, the main CPU 101 sets a value (02) indicating normal symbol display time monitoring to the normal symbol. Set to the control state flag and set the waiting time after confirmation to the waiting time timer. That is, it is set to execute the process of step S133 after the waiting time after determination has elapsed. If this process ends, the process moves to a step S133.

  In step S133, normal symbol display time monitoring processing is performed. In this process, the main CPU 101 extracts a random number value and stores it in the main ROM 102 when the normal symbol control state flag is a value (02) indicating normal symbol display time monitoring. With reference to the normal symbol winning table, it is determined whether or not the normal symbol lottery is won. When the normal symbol lottery is won, the main CPU 101 sets a value (03) indicating the release of the normal electric character in the normal symbol control state flag, and when the normal symbol lottery is not won, the normal symbol game end process is performed. Is set to the normal symbol control state flag. If this process ends, the process moves to a step S134 or a step S135.

  In step S134, an ordinary electric accessory release process is performed. In this process, when the normal symbol control state flag is a value (03) indicating that the normal electric accessory is released, the main CPU 101 sets the normal electric accessory release flag and is the time for opening the blade member. Set the object release time in the waiting time timer. That is, it is set so that the processing of step S135 is executed after the normal bonus release time has elapsed. Note that the main CPU 101 sets the ordinary electric accessory solenoid 111 (opening the blade member of the ordinary electric accessory 415 in the second start port 414b (see FIG. 4) when the ordinary electric accessory release flag is set. (See FIG. 5) Supply solenoid power. In addition, the main CPU 101 sets the waiting time timer set to “0” when a predetermined number of winnings are made in the second start port 414b or when the normal accessory release time is set in a state where the blade member of the ordinary electric accessory 415 is opened. In the case, the solenoid power is supplied to the ordinary electric accessory solenoid 111, and the blade member of the ordinary electric accessory 415 is closed.

  In step S135, a normal symbol game end process is performed. In this process, when the normal symbol control state flag is a value (04) indicating the normal symbol game end process, the main CPU 101 subtracts 1 from the value of the normal symbol hold storage number counter stored in the main RAM 103, A value (00) indicating the normal symbol storage check process is set in the normal symbol control state flag. When this process is finished, this subroutine is finished.

  Next, processing executed by the sub CPU 201 of the sub control circuit 200 will be described. The sub CPU 201 reads a program from the program ROM 202 and executes a sub control circuit main process in response to power-on. Further, the sub CPU 201 may interrupt the sub control circuit main process and execute the sub control circuit interrupt process even when the sub control circuit main process is being executed. The sub CPU 201 generates a clock pulse every predetermined cycle (for example, 2 milliseconds), and executes a sub control circuit interrupt process in response to this.

[Sub-control circuit interrupt processing]
The sub control circuit interrupt process executed by the sub CPU 201 will be described with reference to FIG. In step S210, random number update processing is performed. In this process, the sub CPU 201 performs a process of saving each register and updating a random number stored in the work RAM 203. Specifically, the sub CPU 201 performs random number update processing so as to increase the count value of the effect pattern determination counter stored in the work RAM 203 by “1”. If this process ends, the process moves to a step S211.

  In step S211, command reception processing is performed. In this process, the sub CPU 201 performs a process of receiving a command transmitted from the main control circuit 100 to the sub control circuit 200 and storing it in the work RAM 203. In this process, the sub CPU 201 performs a process of receiving data transmitted from the main control circuit 100 to the sub control circuit 200 in addition to the command and storing the data in the work RAM 203. If this process ends, the process moves to a step S212.

  In step S212, timer update processing is performed. In this processing, the sub CPU 201 performs processing for updating various timers stored in the work RAM 203. Specifically, a process for updating a timer used in the rendering process or the like is performed. If this process ends, the process moves to a step S213.

  In step S213, command output processing is performed. In this processing, the sub CPU 201 performs processing for outputting various commands to the display control circuit 210, the sound control circuit 220, the lamp control circuit 230, and the operation means control circuit 240. In this process, the sub CPU 201 performs a process of outputting various data to the display control circuit 210, the audio control circuit 220, the lamp control circuit 230, and the operation means control circuit 240 in addition to various commands. When this process is finished, a process for restoring each register to the address before the interrupt process is performed, and this subroutine is finished.

[Sub control circuit main processing]
Next, the sub control circuit main process executed by the sub CPU 201 will be described with reference to FIGS. 17, 18 and 19. As shown in FIG. 17, an initialization process is performed in step S220. In this process, the sub CPU 201 reads the activation program from the program ROM 202 and initializes and sets a flag stored in the work RAM 203 in response to power-on. If this process ends, the process moves to step S221.

  In step S221, random number update processing is performed. In this process, the sub CPU 201 performs a process of updating the initial value of the random number stored in the work RAM 203. If this process ends, the process moves to a step S222.

  In step S222, command analysis processing is performed. As will be described in detail later, in this processing, the sub CPU 201 performs processing for analyzing the command received from the main control circuit 100 and stored in the work RAM 203 in step S211 shown in FIG. This process will be described later. If this process ends, the process moves to a step S224.

  In step S224, display control processing is performed. In this processing, the sub CPU 201 stores data for displaying the effect image on the liquid crystal display device 50 in the work RAM 203. The data for displaying the effect image includes, for example, a derived symbol variation start command described later, time display effect data described later, and the like. Then, the sub CPU 201 transmits the stored data to the display control circuit 210 in the process of step S213 shown in FIG. Based on the data for displaying the effect image from the sub CPU 201, the display control circuit 210 reads various image data such as derived symbol data, background image data, effect image data from the image data ROM 211 and superimposes them. Thus, the image is displayed on the display area 51 of the liquid crystal display device 50. If this process ends, the process moves to a step S225.

  In step S225, voice control processing is performed. In this process, the sub CPU 201 stores data for generating sound from the speaker 14 in the work RAM 203. The sub CPU 201 transmits the stored data to the voice control circuit 220 in the process of step S213 shown in FIG. The sound control circuit 220 generates sound from the speaker 14 based on data for generating sound. If this process ends, the process moves to a step S226.

  In step S226, lamp control processing is performed. In this process, the sub CPU 201 stores data for controlling the lamp 15 including the decorative lamp in the work RAM 203. The sub CPU 201 transmits the stored data to the lamp control circuit 230 in the process of step S213 shown in FIG. The lamp control circuit 230 turns on, blinks, or turns off the lamp 15 based on data for controlling the lamp 15. When this process is finished, this subroutine is finished.

[Command analysis processing]
A subroutine (command analysis process) executed in step S222 in FIG. 17 will be described with reference to FIG. In step S230, a process for determining whether there is a received command is performed. In this process, the sub CPU 201 determines whether or not the command received from the main control circuit 100 is stored in the work RAM 203. If it is determined that the command is stored, the process proceeds to step S231. If it is determined that the command is not stored, this subroutine is terminated.

  In step S231, processing for analyzing the command received in the sub control circuit interrupt processing is performed. In this processing, the sub CPU 201 performs processing for analyzing commands and data received from the main control circuit 100 and stored in the work RAM 203 in step S211 shown in FIG. If this process ends, the process moves to a step S232. These commands and data include the demo display command, derived symbol designation command, variation pattern data indicated by the variation pattern designation command, jackpot type command, data indicating the value of the probability variation state variation counter, Data indicating a value, a big hit start command, a small hit start command, data indicating a value of a probability change flag, data indicating a value of a time reduction flag, a start opening prize command, and the like are included.

  Further, the sub CPU 201 performs a process of storing the variation pattern data indicated by the analyzed variation pattern designation command in the variation pattern storage area. In the present embodiment, the work RAM 203 has a fluctuation pattern storage area, and this fluctuation pattern storage area includes a fluctuation pattern storage area (0) to a fluctuation pattern storage area (4). The variation pattern data indicated by the analyzed variation pattern designation command is sequentially stored in the variation pattern storage area (0) to the variation pattern storage area (4). The sub CPU 201 performs an effect pattern determination process, which will be described later, based on the variation pattern data stored in the variation pattern storage area (0). As described above, in this embodiment, the variation pattern designation command corresponding to the suspended display of the special symbol is also stored in the variation pattern storage area (0) to the variation pattern storage area (4) of the work RAM 203. The sub CPU 201 reads a variation pattern designation command stored in the variation pattern storage area (0) to the variation pattern storage area (4), thereby enabling a so-called “prefetching effect”.

  In step S232, it is determined whether or not a variation pattern designation command has been received. In this process, the sub CPU 201 determines whether or not the variation pattern designation command is included in the command received from the main control circuit 100 as a result of the analysis in step S231, and determines that the variation pattern designation command is included. If so, the process proceeds to step S233. If it is determined that the variation pattern designation command is not included, the process proceeds to step S234.

  In step S233, effect pattern determination processing is performed. Although details will be described later, in this process, the sub CPU 201 determines an effect pattern with reference to the effect table based on the change pattern designation command. When this process is finished, this subroutine is finished.

  In step S234, processing for determining whether or not a derived symbol designation command has been received is performed. In this processing, the sub CPU 201 determines whether or not the derived symbol designation command is included in the command received from the main control circuit 100 as a result of the analysis in step S231, and determines that the derived symbol designation command is included. If so, the process proceeds to step S235, and if it is determined that the derived symbol designation command is not included, the process proceeds to step S236.

  In step S235, a process for determining a derived symbol is performed. In this process, the sub CPU 201 determines a derived symbol corresponding to the derived symbol designation command received from the main control circuit 100, and displays the derived symbol on the display area 51 (see FIG. 4) of the liquid crystal display device 50. Is stored in the work RAM 203. Specifically, the sub CPU 201 determines the derived symbol indicating the big hit if the derived symbol designation command is associated with the big hit, and determines the derived symbol indicating the small hit if the derived symbol designation command is associated with the small hit. If it is associated with the loss, the derived symbol indicating the loss is determined. If this process ends, the process moves to a step S236.

  Here, in the present embodiment, for example, the derived symbol is displayed in a variable manner on the display area 51 (see FIG. 4) of the liquid crystal display device 50 in a mode in which three numbers from “0” to “9” are arranged. Stopped display. In the derived symbol indicating the big hit, the stop display mode is, for example, that all three numbers are the same number, and this number is an odd number. Further, in the derived symbol indicating the small hit, the stop display mode is, for example, that all three numbers are the same number, and this number is an even number. Further, in the derived symbol indicating the loss, the stop display mode is not, for example, that all three numbers are the same number. Further, when the sub CPU 201 loses from the quasi-continuous production without reaching, for example, the sub CPU 201 derives to indicate the loss so that the stop display mode in which numbers are continuous such as “123” and “234” is not obtained. Determine the design. Furthermore, in the case of reaching and losing, the derived symbols are determined such that the left and right numbers are the same and the central numbers are different, such as “121” and “232”. . Therefore, if the stop display mode of the derived symbol does not become a stop display mode in which consecutive numbers such as “123” and “234” are continuous or reach display mode, it is confirmed that the pseudo-ream has ended. The effect display is shown.

  In step S235, the sub CPU 201 sets a derived symbol variation start command for starting the variation display of the determined derived symbol. Then, the sub CPU 201 transmits the derived symbol variation start command and variation pattern data in the variation pattern storage area (0) to the display control circuit 210 in the process of step S213 shown in FIG. Based on the derived symbol variation start command, the display control circuit 210 starts the variation display of the derived symbol in the display area 51 (see FIG. 4) of the liquid crystal display device 50 and stops the display after the variation time based on the variation pattern data has elapsed. To do. At this time, the sub CPU 201 acquires the derived symbol variation start time when the variation display of the derived symbol is started from the RTC 204 and stores it in the work RAM 203. The sub CPU 201 shifts the data in the variation pattern storage area (1) to the variation pattern storage area (4) from the variation pattern storage area (0) to the variation pattern storage area (3) after the display of the derived symbol is stopped. Process).

  In step S237, processing corresponding to the received other command is performed. In this processing, the sub CPU 201 performs processing corresponding to commands other than the variation pattern designation command and the derived symbol designation command. When this process is finished, this subroutine is finished.

[Direction pattern determination processing]
The subroutine (effect pattern determination process) executed in step S233 in FIG. 18 will be described with reference to FIG. In step S240, effect pattern determination processing is performed. In this process, the sub CPU 201 designates the variation pattern designation command with reference to the effect table based on the variation pattern designation command analyzed in step S231 shown in FIG. 18 and the random value extracted for the effect pattern determination. The effect pattern corresponding to the changed pattern is extracted. In the production table, the variation pattern shown in the variation pattern designation command has a derived pattern variation time, a random value for determining the production pattern with a predetermined width, selection rate, production pattern, production content, winning type, and design designation. Commands are associated and stored in the program ROM 202. If this process ends, the process moves to a step S241.

[Description of production pattern]
Here, an effect pattern is demonstrated, referring FIG.24 and FIG.25. FIG. 24 illustrates an example of a normal effect pattern having no pseudo-ream, and FIG. 25 is an explanatory diagram illustrating an example of a pseudo-ream effect pattern including a pseudo-ream.

  According to the present embodiment, as described above, the longer the variation pattern of the special symbol, the easier it is to select the variation pattern in the big hit. For this reason, even in the variation of the identification symbol in the identification symbol game displayed on the liquid crystal display device 50, the longer the variation time, the easier it is to reach the big hit. Also, before the big win display in the identification symbol game, that is, all the three identification symbols are stopped in the same display mode, the reach state, that is, the two identification symbols are always stopped in the same display mode, and the remaining one identification symbol is displayed. Is in a state of changing display mode. Therefore, when reach occurs several seconds after the change of the identification symbol starts, the longer the reach effect time, the easier it is to reach the big hit.

[Description of normal production pattern]
First, a normal effect pattern will be described with reference to FIG.
The effect pattern that is most easily selected as an effect pattern in losing is the change of the identification symbol as effect pattern A and then stops. In the effect pattern B, the identification symbol starts to change and reaches a reach state, and the identification symbol stops after reaching the reach effect. In the effect pattern C, the identification symbol starts to change and reaches a reach state, and the identification symbol stops after the reach effect and the first development effect. Hereinafter, for the convenience of explanation, the first development effect is referred to as development 1. Similarly, the second to fourth development effects are referred to as developments 2 to 4. According to the present embodiment, development 4 is the final development stage. In the effect pattern D, the identification symbol starts to change and reaches a reach state, and the identification symbol stops after reaching, development 1, and development 2. In the effect pattern E, the identification symbol starts to change and reaches a reach state, and the identification symbol stops after reaching, development 1, development 2, and development 3. In the effect pattern F, the identification symbol starts to change and reaches a reach state, and the identification symbol stops after reaching the reach effect, development 1, development 2, development 3, and development 4. Like the production pattern B, when the reach production time is short, it is easy to lose. However, as shown in the production patterns C to F, for example, the development 1, the development 2, the development 3, and the development 4 As reach production develops in stages, the likelihood of reaching a big hit increases. Note that the above-described normal effect pattern is merely an example, and there may be an effect pattern that does not include pseudo-continuations other than the effect patterns A to F.

[Description of production pattern including pseudo-ream]
Next, the pseudo continuous effect pattern will be described with reference to FIG.
When the quasi-continuous designation data is included in the variation pattern designation command transmitted from the main control circuit 100 to the sub-control circuit 200, the pseudo-continuous effect is displayed in the display area 51 of the liquid crystal display device 50.
FIG. 25 is an explanatory diagram illustrating an example of an effect pattern including a pseudo-continuous effect, and according to the present embodiment, there are effect patterns G to O as the effect patterns including the pseudo-continuous effect. In the pseudo-continuous production, the first re-variation display is performed in the pseudo ream (1), the second re-variation display is performed in the pseudo-ream (2), and the third and fourth re-variation display is performed. These cases are referred to as pseudo-ream (3) and pseudo-ream (4). Further, according to the present embodiment, the reach in the pseudo-continuous effect occurs at a time point before the time point of any one of the development 1, development 2, development 3 and development 4 in the effect pattern in which the pseudo-continuous effect is not performed. . Specifically, the quasi-ream (1) reaches before the development 1, the quasi-ream (2) reaches before the development 2, the quasi-ream (3) reaches before the development 3, and before the development 4. The reach of pseudo-ream (4). In this way, the number of pseudo-continuations and the development stage of reach production are associated with each other. For example, in a pattern in which the identification symbol stops after the development to development 3 as in the production pattern E shown in FIG. Up to 3 pseudo-reams are possible.

  The effect patterns G to I shown in FIG. 25 are examples when the re-variable display is performed once in the pseudo-continuous effect, and the effect pattern G is the reach or pseudo-continuous after performing the pseudo-continuous (1). The case where an identification symbol stops without shifting to (2) is shown. The effect pattern H shows a case where after the pseudo-ream (1) is performed, the process proceeds to reach, and further proceeds to development 1, and the identification symbol is stopped. The effect pattern I shows a case where after the pseudo-ream (1) is performed, the identification symbol is stopped after shifting to reach and then shifting to development 1 and further development 2. In addition, in the pattern shown in the production pattern I, the production pattern may include a pattern in which the identification symbol stops after the transition from the development 2 to the development 3 and further to the development 4 without stopping.

  The production patterns J to L are examples when the re-variable display is performed twice in the pseudo-continuous production. The production pattern J reaches the reach after performing the pseudo-continuous (1) and the pseudo-continuous (2). The case where the identification symbol is stopped after the transition to the development 2 is shown. The effect pattern K shows a case where after the pseudo-ream (1) and the pseudo-ream (2) are performed, the process proceeds to reach, and further proceeds to development 2 and development 3 to stop the identification symbol. The effect pattern L shows a case where after the pseudo-ream (1) and the pseudo-ream (2) are performed, the process proceeds to reach, and further proceeds to development 2, development 3, and development 4 to stop the identification symbol.

  The production patterns M to N are an example in the case where the re-variable display is performed three times in the pseudo-continuous production, and the production pattern M performs the pseudo-continuous (1), the pseudo-continuous (2), and the pseudo-continuous (3). After that, the case where it shifts to reach, further shifts to development 3, and the identification symbol stops is shown. The production pattern N is a case where the pseudo-ream (1), the pseudo-ream (2), and the pseudo-ream (3) are performed, and then the process proceeds to reach, and further proceeds to development 3 and development 4 to stop the identification symbol. Show.

  The pattern shown in the production pattern O is an example in the case where the re-variable display is performed four times in the pseudo-continuous production, and the pseudo-continuous (1), pseudo-continuous (2), pseudo-continuous (3), and pseudo-continuous (4). After performing the above, a case where the identification symbol is stopped is shown by moving to reach and then proceeding to development 4.

  According to the present embodiment, the effect pattern B and the effect pattern G have the same variation time. The effect pattern C and the effect pattern H have the same variation time. The effect pattern D, the effect pattern I, and the effect pattern J have the same variation time. The effect pattern E, the effect pattern K, and the effect pattern M have the same variation time. The production pattern F, the production pattern L, the production pattern N, and the production pattern O have the same variation time. The effect pattern including the above-described pseudo-ream is merely an example, and there may be effect patterns other than the effect patterns G to O.

  The effect patterns A to O are effect image display data at the start of variation of the identification symbol, effect image display data at the time of stop, effect image display data at the time of reaching, development image display data of each of development 1 to development 4, pseudo It consists of any combination of effect image display data of each of the series (1) to the pseudo series (4). The effect image display data is stored in the image data ROM 211 that is read by the display control circuit 210. The display control circuit 210 forms one continuous pseudo continuous effect image by combining the pseudo continuous (1) to the pseudo continuous (4) according to the number of pseudo continuous. For example, in the case of the effect pattern O, the display control circuit 210 starts pseudo change (1) to pseudo change (4) at the start of fluctuation from the image data ROM 211 based on the data of the effect pattern O set in the work RAM 203. When the reach occurs, the development image 4 when the reach occurs, and the stop effect image display data are read out and combined to form one continuous effect image corresponding to the effect pattern O.

  In addition to the effect image display data described above, the image data ROM 211 integrates the pseudo-series (1) and the pseudo-series (2), except for the pseudo-series (2) following the pseudo-series (1). Production image display data, pseudo-ream (2), and pseudo-ream (3) that form a pseudo-ream that varies three identification symbols 52 (see FIG. 26) from the start of ream (1) to the end of the pseudo-ream (2). The effect image which forms the pseudo | simulation series which fluctuates three identification symbols 52 from the start of pseudo | simulation series (2) to the end time of pseudo | simulation series (3) except the pseudo series (3) following a pseudo series (2). The display data, the pseudo-series (1) to the pseudo-series (3) are integrated, and the pseudo-series (1) starts from the pseudo-series (3) except for the pseudo-series (2) and the pseudo-series (3). Effect image display data forming a pseudo-series that fluctuates the three identification symbols 52 until the end point of It has been.

  In the effect table, the effect pattern having the same change time is associated with the variation pattern transmitted from the main control circuit 100, and identification information independent for each effect pattern corresponding to each variation pattern. Is attached.

  Returning to FIG. 19, in step S <b> 241, processing for determining whether or not to execute the pseudo-continuous effect is performed. In this process, the sub CPU 201 determines whether or not the variation pattern specification command includes pseudo continuous specification data for specifying execution of the pseudo continuous effect, and determines that the pseudo continuous specification data is included. In step S242, the process is transferred to step S242. If it is not determined that pseudo-continuous designation data is included, the process proceeds to step S246.

  In step S242, the sub CPU 201 performs a process of extracting an effect pattern including a pseudo-continuity, that is, a pseudo-continuous effect pattern, from the effect pattern extracted in step S241. Specifically, when data specifying the variation pattern of HN21 (see FIG. 22) is transmitted from the main control circuit 100, the sub CPU 201 determines that the effect pattern corresponding to the variation pattern of HN21 is the effect pattern E and the effect. Since the pattern K and the production pattern M are the patterns K and the production pattern M, the two patterns are extracted. If this process ends, the process moves to a step S243.

  In step S243, a process of determining a pseudo continuous effect pattern is performed. In this process, if there is one pseudo-continuous effect pattern extracted in step S242, the sub CPU 201 determines that pattern as an effect pattern in the identification symbol game. A process of selecting a pseudo-continuous effect pattern and determining the pattern as an effect pattern in the identification symbol game is performed. Specifically, when the effect pattern K and the effect pattern M are extracted in step S242 as described above, one effect pattern is selected from the two by random lottery or the like. If this process ends, the process moves to a step S244.

  In step S244, pseudo continuous effect pattern setting processing is performed. In this process, the sub CPU 201 performs a process of storing the pseudo continuous effect pattern determined in step S243 in the work RAM 203. Specifically, when the effect pattern M is determined in step S243, in the identification symbol game displayed on the liquid crystal display device 50, after the start of fluctuation, the pseudo ream (1), the pseudo ream (2), the pseudo ream ( After performing 3), an effect including a pseudo-ream, such as shifting to reach, further shifting to development 3 and stopping the identification symbol, is executed. If this process ends, the process moves to a step S245.

  In step S245, a pseudo continuous number notification effect setting process is performed. In this process, the sub CPU 201 obtains information on the number of pseudo-continuations from the contents of the effects stored in the effect table in association with the effect pattern set in step S244, and identifies the pseudo-continuous effects displayed on the liquid crystal display device 50. When the symbol is temporarily stopped, the liquid crystal display device 50 performs a process of displaying a notification image (for example, a piece image 501 shown in FIG. 26) corresponding to the number of pseudo consecutive times. Specifically, when the effect pattern M is determined in step S243, each of the pseudo-continuous (1), pseudo-continuous (2), and pseudo-continuous (3) is temporarily stopped when the three pieces of identification information are temporarily stopped. ), A notification image for notifying that the pseudo ream (2) and the pseudo ream (3) have been executed is displayed on the liquid crystal display device 50. Note that the notification image data corresponding to the number of pseudo-continuations is stored in the image data ROM 211. When this process is finished, this subroutine is finished.

  In step S246, the sub CPU 201 performs a process of extracting an effect pattern that does not include a pseudo-ream in the effect pattern extracted in step S240. Specifically, when data designating the variation pattern of HN21 is transmitted from the main control circuit 100, the sub CPU 201 determines that the production pattern corresponding to the variation pattern of HN21 is production pattern E, production pattern K, and production. The pattern M is the pattern M, and the pattern that does not include the pseudo-ream is the effect pattern E. Therefore, this one pattern is extracted. If this process ends, the process moves to a step S247.

  In step S247, the effect pattern is determined. In this process, if there is one effect pattern extracted in step S246, the sub CPU 201 determines that pattern as an effect pattern in the identification symbol game. If there are a plurality of effect patterns, the sub CPU 201 determines one effect pattern by random lottery or the like. Is selected, and the pattern is determined as an effect pattern in the identification symbol game. Specifically, since only the effect pattern E is extracted as described above in step S246, the effect pattern E is selected. If this process ends, the process moves to a step S248.

  In step S248, effect pattern setting processing is performed. In this process, the sub CPU 201 performs a process of storing the effect pattern determined in step S247 in the work RAM 203. Specifically, since the effect pattern E is determined in step S247, after the start of fluctuation, the reach is reached, the reach effect is shifted to development 1, development 2, and development 3, and the identification symbol is stopped. It will be. When this process is finished, this subroutine is finished.

[Description of production screen]
FIG. 26 is an explanatory diagram illustrating an example of an effect screen displayed on the liquid crystal display device 50 according to the present embodiment.

  FIG. 26A is an example of an effect screen showing the state after the start of variation in the three identification symbols 52 for effects, and when the first start port 414a or the second start port 414b is won, the liquid crystal display device The three identification symbols 52 for effect displayed in the 50 display areas 51 are variably displayed. Then, in the case of a temporary stop in a stop display mode (for example, a serial number such as 1, 2, 3) which is a condition for generating a pseudo-continuous, the right side of the rectangular display area 51 is shown in FIG. Thus, a right triangle piece image 501a is arranged.

  Next, after the three identification symbols 52 for production re-variate from the temporarily stopped state as shown in FIG. 26 (c), the three identification symbols 52 for production are in a stopped state with different display modes. In the case where the display of variation of the identification symbol 52 based on the next hold information is started and the reach state is reached, an image display as a reach effect is performed. When the three identification symbols 52 for presentation are temporarily stopped in the stop display mode that is the pseudo-ream occurrence condition, as shown in FIG. 501b is arranged. At this point, the player can easily grasp that the pseudo-ream has been performed twice by displaying the piece images 501a and 501b and the two piece images 501.

  Furthermore, in the stop display mode, which is a condition for generating pseudo-continuations after the three identification symbols 52 for production shown in FIG. 26 (d) have changed again from the temporarily stopped state as shown in FIG. 26 (e). In the case of temporary stop, as shown in FIG. 26 (f), a right triangle piece image 501c is arranged above the display area 51, and the three identification symbols 52 for production include three piece images 501a and 501b. , 501c are arranged in a triangular region formed in the center. At this point, the player can easily grasp that the pseudo-ream has been performed three times.

  Furthermore, when the three identification symbols 52 for production re-change from the temporary stop state and then temporarily stop in the stop display mode, which is a condition for generating a pseudo-ream, as shown in FIG. 26 (g). In the center of the display area 51, a triangular piece image 501d that matches the triangle formed by the three piece images 501a, 501b, and 501c is arranged. Accordingly, the display area 51 is covered with the four piece images 501a, 501b, 501c, and 501d. At this point, the player can easily grasp that the pseudo-ream has been performed four times, in other words, that the pseudo-ream has reached the final number of times. Thereafter, as shown in FIG. 26 (h), the two identification symbols 52 are stopped and displayed in the same display mode, reach state is reached, and reach effect is started. According to the present embodiment, since the pseudo-ream is performed four times, the reach effect of the development 4 is started.

  Thereby, it becomes possible for the player to easily grasp how many times the pseudo-ream is performed according to the number of piece images 501, and expecting that the display area 51 is covered with the piece image 501. Can be enjoyed.

  Note that, according to the present embodiment, for example, when the effect pattern determined in step S243 shown in FIG. 19 is the effect pattern L shown in FIG. Will be displayed. For this reason, there is a possibility that the player will have less expectation for the big hit when the pseudo ream (2) ends.

  Therefore, when the effect pattern is determined to be two or more pseudo-reams in step S243 in FIG. 19, in the process of step S245 in FIG. 19, the big hit gaming state is entered at the start of the pseudo-ream (2) or pseudo-ream (3). A notification image that indicates the expected degree of transition may be set to be displayed with a predetermined probability. For example, when the effect pattern L is determined in step S243, the big hit reliability when the development 4 appears is displayed with high probability at the start of the pseudo-ream (2), and other effect patterns are determined. In such a case, the big hit reliability when the development 3 appears is set to be displayed with high probability. Thereby, for example, when the production patterns J, K, and M to O are determined in step S243, the big hit reliability (for example, 30%) when the development 3 appears at the start of the pseudo-ream (2). Is often displayed, the player expects the pseudo-ream to continue to increase the reliability. In addition, when the production pattern L is determined in step S243, the big hit reliability (for example, 60%) when the development 4 appears is often displayed at the start of the pseudo sequence (3). The player will expect to reach as it is.

  In addition, according to the present embodiment, the extent to which the production develops after the pseudo-ream ends and becomes reach is where the player is interested. Therefore, an effect display that suggests the development of the effect after the end of the pseudo-ream may be performed. For example, you may suggest the development stage in the production performed after a pseudo | simulation end is completed by switching the color of the piece image 501. FIG. For example, the color of the piece image 501 is determined by random number lottery. If it is developed 1, it is easy to determine the case where the color of the piece image 501 is not changed, and if it is developed 2, blue is easily determined as the color of the piece image 501. Then, green may be easily determined as the color of the piece image 501, and red may be easily determined as the color of the piece image 501 in the development 4. Thereby, it becomes possible to give the player a sense of expectation regarding the effect after the end of the pseudo-continuation while maintaining the expectation by the pseudo-ream.

  FIG. 27 is an explanatory diagram showing a display example of a notification image that suggests the expected degree of transition to the big hit gaming state. For example, when the effect pattern L is determined in step S243 in FIG. 19, as shown in FIGS. 27A to 27D, the identification symbol 52 temporarily stops twice after the variation of the identification symbol 52 is started. Piece images 501a and 501b are displayed. When the next re-variation starts, a piece image 502 having the same shape and different color as that of the piece image 501c is displayed as shown in FIG. 27E. Character information 503 such as “reliability 60% if reach is reached” is displayed in an overlapping manner. Through this character information 503, the player can grasp that the big hit can be expected even if the pseudo-ream does not continue and the reach is reached.

  Thereafter, before reaching reach as shown in FIG. 27 (f), the piece image 502 and the character information 503 are erased, and when reaching as shown in FIG. 27 (g), the piece image 501a and piece image 501b are reached. When the color changes to red, the degree of expectation for shifting to the development 4 development becomes high as shown in FIG. Thereafter, in the case of a big hit, the three identification symbols 52 stop in the same display mode.

  In this way, in step S243 in FIG. 19, for example, when an effect pattern having a high jackpot reliability but a small number of pseudo-continuations is determined, such as effect pattern M and effect pattern L, before reaching reach. By displaying the character information 503 regarding the degree of jackpot expectation, it is possible to make the player think that the person who can reach the jackpot is more likely to reach the jackpot if he / she reaches the reach rather than continuing. In this way, it is possible to give a new interest to the player that he / she wants the pseudo-ream not to continue.

  As described above, according to the first embodiment configured as described above, the re-variation number suggesting effect display (display of the pseudo-continuous number) is continuously performed according to the number of times the control of re-variable display is performed (pseudo-continuous number). By performing separately from the display of the effect image (pseudo-continuous effect image), it is possible to display the continuous effect image display to the player in an easy-to-understand relationship with the number of re-variable displays. Become. Thereby, the effect which raises the expectation by the original pseudo-ream for a player can be improved.

  Further, according to the present embodiment, a special condition such as changing the color of the re-variation number suggesting effect display (piece image 501) when the effect develops after reaching the reach from the pseudo-continuous image, for example. By switching to the image display, maintaining the effect of increasing the player's expectation for the transition to the advantageous gaming state by the original pseudo-relation for the player, the player for the transition to the advantageous gaming state by the development effect It is possible to further increase the sense of expectation.

  In addition, according to the present embodiment, by performing the expectation suggestion effect display indicating the expectation degree of the transition to the advantageous state, the player guesses how much the expectation degree for the transition to the advantageous state is increased. This makes it possible to further increase the player's expectation for the transition to an advantageous state.

[Second Embodiment]
Next, a second embodiment of the present invention will be described. In addition, in the pachinko gaming machine 1 of the second embodiment, the same members as those in the pachinko gaming machine 1 of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. The pachinko gaming machine 1 of the second embodiment is the same as the structure of the pachinko gaming machine 1 in the first embodiment, but part of the processing executed by the sub CPU 201 of the sub control circuit 200 is different. Specifically, in the second embodiment, the sub control circuit interruption process shown in FIG. 16 and the effect pattern determination process shown in FIG. 19 in the first embodiment are different.

[Sub-control circuit interrupt processing]
FIG. 28 is a flowchart showing the sub control circuit interrupt process in the second embodiment. Note that the same step number is assigned to the same process as the sub control circuit interrupt process in the first embodiment shown in FIG. 16, and a detailed description thereof is omitted.
As shown in FIG. 28, steps S210 to S212 are the same as those in the first embodiment shown in FIG. 18, and after the timer update process in step S212 is completed, the process proceeds to step S300.

  In step S300, effect button operation determination processing is performed. In this processing, based on a signal output in response to the operation of the sub CPU 201 effect button, it is determined what operation the player has performed, and processing for setting various data in the work RAM 203 is performed based on the determination. Details of this process will be described later. When this process is completed, the process proceeds to step S213. When the command output process of step S213 is completed, a process for restoring each register to the address before the interrupt process is performed, and this subroutine is terminated. .

[Direction button operation determination processing]
FIG. 29 is a flowchart showing an effect button operation determination process in the sub-control circuit interrupt process of FIG.
In step S <b> 310, the sub CPU 201 stores the signal from the effect button 16 in the work RAM, and performs processing for analyzing the content specified by the operation of the effect button 16. If this process ends, the process moves to a step S311.

  In step S <b> 311, the sub CPU 201 determines whether or not the operation of the effect button 16 is a menu screen display for setting the pseudo consecutive number, and specifies the menu screen display for setting the pseudo consecutive number. If it is determined that, the process proceeds to step S312. If it is not determined that the menu screen display for setting the quasi-continuous number is specified, the process proceeds to step S313.

  In step S <b> 312, the sub CPU 201 performs processing for setting data for displaying a menu screen for setting the number of pseudo consecutive times in the work RAM 203. According to the present embodiment, a menu screen is displayed on the liquid crystal display device 50 that allows the player to select from five types of pseudo-ream 0 times to pseudo-ream 4 times. When this process is finished, this subroutine is finished.

  In step S313, the sub CPU 201 determines whether or not the operation of the effect button 16 is for specifying the number of pseudo consecutive times, and if it is determined that the number of pseudo continuous numbers is specified, the process proceeds to step S314. Move processing. If it is not determined that the number of pseudo consecutive times is specified, the process proceeds to step S315.

  In step S <b> 314, the sub CPU 201 performs a process of setting the data of the pseudo continuous number designated by the player in the work RAM 203. According to this embodiment, the player can select from five types of pseudo-ream 0 times to pseudo-ream 4 times. When this process is finished, this subroutine is finished.

  In step S315, the sub CPU 201 performs other processing corresponding to the operation of the effect button. When this process is finished, this subroutine is finished.

[Direction pattern determination processing]
FIG. 30 is a flowchart showing an effect pattern determination process in the second embodiment.
In the effect pattern determination process in the second embodiment, in step S240, as in the first embodiment, the sub CPU 201 performs a process of extracting an effect pattern corresponding to the variation pattern designated by the variation pattern designation command. If this process ends, the process moves to a step S241.

  In step S241, processing for determining whether or not to execute a pseudo-continuous effect is performed. In this process, as in the first embodiment, if the sub CPU 201 determines that the pseudo-continuous designation data is included in the variation pattern designation command, the process proceeds to step S320. If it is not determined that pseudo-continuous designation data is included, the process proceeds to step S246.

  In step S320, a process is performed to determine whether or not the player has designated no pseudo-ream. In this process, the sub CPU 201 determines whether or not the player has designated no pseudo-continuation based on the data set in the work RAM 203 in step S314 shown in FIG. 29, and the player has designated no pseudo-continuation. If it is determined, the process proceeds to step S246. If it is not determined that pseudo-continuous designation data is included, the process proceeds to step S242.

  In step S242, as in the first embodiment, the sub CPU 201 performs a process of extracting an effect pattern including pseudo-continuations, that is, a pseudo-continuous effect pattern, from the effect patterns extracted in step S241. If this process ends, the process moves to a step S243.

  In step S243, a process of determining a pseudo continuous effect pattern is performed. In this process, as in the first embodiment, when the number of pseudo continuous effect patterns extracted in step S242 is one, the sub CPU 201 determines that pattern as an effect pattern in the identification symbol game. Performs a process of selecting one pseudo-continuous effect pattern by random lottery or the like and determining that pattern as an effect pattern in the identification symbol game. If this process ends, the process moves to a step S321.

  In step S321, it is determined whether or not the number of pseudo-continuations is greater than the number of pseudo-continuations specified by the player. In this process, the sub CPU 201 determines whether or not the number of pseudo-continuations in the pseudo-continuous effect pattern determined in step S243 is greater than the number of pseudo-continuations specified by the player based on the data set in the work RAM 203 in step S314 shown in FIG. The process which determines is performed. If it is determined that the number of pseudo-continuations is greater than the number of pseudo-continuations specified by the player, the process proceeds to step S322. If it is not determined that the number of pseudo-reams is greater than the number of pseudo-reams designated by the player, the process proceeds to step S244.

  In step S322, a process of changing the pseudo continuous effect pattern is performed. In this process, the sub CPU 201 performs a process of changing the data of the pseudo-continuous effect pattern so that the pseudo-continuous number of times in the pseudo-continuous effect pattern determined in step S243 becomes the player-specified pseudo-continuous number of times. A specific example of this process will be described later with reference to FIGS. If this process ends, the process moves to a step S244.

  In step S244, pseudo continuous effect pattern setting processing is performed. In this processing, the sub CPU 201 performs processing for storing the pseudo continuous effect pattern determined in step S243 or the pseudo continuous effect pattern changed in step S322 in the work RAM 203. When this process is finished, this subroutine is finished. In the second embodiment as well, similarly to the first embodiment, when the process of step S244 is completed, the pseudo-number-of-times notification effect setting process of step S245 may be performed.

  In step S246, similarly to the first embodiment, the sub CPU 201 performs a process of extracting an effect pattern that does not include pseudo-continuations in the effect pattern extracted in step S240. If this process ends, the process moves to a step S247.

  In step S247, the effect pattern is determined. In this process, as in the first embodiment, the sub CPU 201 determines the pattern as an effect pattern in the identification symbol game when there is one effect pattern extracted in step S246, and if there are a plurality of effect patterns, One effect pattern is selected by random number lottery or the like, and the pattern is determined as an effect pattern in the identification symbol game. If this process ends, the process moves to a step S248.

  In step S248, effect pattern setting processing is performed. In this process, the sub CPU 201 performs a process of storing the effect pattern determined in step S246 in the work RAM 203 as in the first embodiment. When this process is finished, this subroutine is finished.

[Pseudo continuous number setting menu screen]
Next, the pseudo continuous number setting menu screen will be described. On the basis of the menu screen display data set in step S312 of FIG. 29, a pseudo continuous number setting menu 600 is displayed on the liquid crystal display device 50 as shown in FIG.
In the pseudo continuous number setting menu 600, the current setting, the operation method, and the selection item of the maximum pseudo continuous number are displayed. In the example shown in FIG. 31, the selection items are “no quasi-continuous”, “1 time (1 quasi-continuous)”, “2 times (2 quasi-continuous)”, and “3 times (3 quasi-continuous)”. , “4 times (4 pseudo-reams)” and “cancel”, and 6 items. Then, the player operates the effect button 16 to determine the maximum number of pseudo reams.

[Change of pseudo-direction production]
According to the second embodiment, when the player selects “4 times” in the pseudo-continuous number setting menu 600, the process does not proceed to step S322 in FIG. I will not.
Here, in step S243 of FIG. 30, for example, when the pseudo ream (4) is selected as shown in the effect pattern O (FIG. 25), the player selects “once” in the pseudo repetitive number setting menu 600. If any of “3 times” is selected, the process proceeds to step S322 in FIG.

  When the player has selected “three times” as the maximum number of pseudo-reams, as shown in FIG. 32, the pseudo-ream (1) and the pseudo-ream (2) in the production pattern O are integrated once. In the production pattern O, the pseudo sequence (3) is switched to the pseudo sequence (2), and the pseudo sequence (4) is switched to the pseudo sequence (3). Specifically, instead of pseudo-continuous (1) and pseudo-continuous (2) in the effect pattern O, it is changed to effect image data in which the identification symbol 52 varies from the start of the pseudo-continuous (1) to the end of the pseudo-continuous (2). The pseudo-series (3) and the pseudo-series (4) are changed to effect image data of the pseudo-series (2) and the pseudo-series (3).

  Similarly, when the player has selected “2 times” as the maximum number of pseudo-reams, the pseudo-ream (1), pseudo-ream (2), and pseudo-ream (3) in the production pattern O are integrated. As shown in FIG. 32 (b), the pseudo sequence (4) in the effect pattern O is switched to the pseudo sequence (2).

  Similarly, when the player has selected “1 time” as the maximum number of pseudo-reams, the pseudo-ream (1), pseudo-ream (2), pseudo-ream (3) and pseudo-ream ( 4) are integrated into one pseudo-ream (1), and after the pseudo-ream (1) starts, after the time from the pseudo-ream (1) to the pseudo-ream (4) in the effect pattern O has elapsed, Switch to reach. Thereby, the effect pattern of pseudo ream (4) is switched to the effect pattern of pseudo ream (1).

  Further, in the case where the player has selected “2 times” as the maximum number of pseudo-reams, when the effect pattern is determined to be the number of times of pseudo-reams in step S243 of FIG. 30, for example, the effect shown in FIG. When the pattern N is determined, two of the three pseudo runs are integrated into one pseudo run, resulting in two pseudo runs as shown in (a1) of FIG. Further, when the player selects “1” as the maximum number of pseudo-reams, the three pseudo-reams are integrated into one pseudo-ream, and 1 as shown in (a2) of FIG. It becomes a pseudo-ream of times.

  Further, in the case where the player has selected “one time” as the maximum number of pseudo-reams, and the effect pattern is determined to be two times in step S243 of FIG. 30, for example, the effect shown in FIG. When the pattern J is determined, two pseudo-series are integrated into one pseudo-series, and as a result, one pseudo-series is formed as shown in (b1) of FIG.

  If the player has selected “no pseudo-ream”, it is determined from the effect patterns that do not include the pseudo-ream by the process of step S320 of FIG.

  According to the second embodiment configured as described above, a normal pseudo-continuous effect display is performed by a player's operation, or a special pseudo-continuous image obtained by excluding a specific one-effect image display from the normal pseudo-continuous effect display. It is possible to select whether or not to display effects. In other words, it becomes possible for the player to select the number of pseudo-continuations. For this reason, it is possible to display a pseudo-continuous effect that can increase the player's expectation, instead of displaying a pre-prepared pseudo-continuous effect. A feeling can be maintained.

  Although the second embodiment has been described above, the second embodiment is not limited to the above-described one. For example, according to the second embodiment described above, when the player sets the maximum number of pseudo-continuations to 3, the effect display in the temporary stop state at the start of the pseudo-continuation (2) in the effect pattern (O) is performed. It is excluded. For this reason, the player feels that the time from the pseudo ream (1) to the start of the pseudo ream (2) is relatively long, and the pseudo ream (2) starts 2 times in a relatively short time after the start of the pseudo ream (2). It seems to continue. In other words, when the player feels that the pseudo-reams are concentrated in the latter half of the production up to reach, the player has a high expectation for the big hit.

  However, according to the second embodiment, for example, when the maximum number of pseudo-reams is set to 3, the production pattern of the pseudo-ream (4) is from the occurrence of the pseudo-ream (1) to the occurrence of the pseudo-ream (2). In addition to the latter half pattern with a relatively long time, as shown in FIG. 34 (a), the first half pattern should have a relatively short time from the occurrence of the pseudo ream (1) to the occurrence of the pseudo ream (2). Is also possible. Therefore, as shown in FIG. 35, when the maximum number of pseudo-reams is set to 3, a pseudo-ream type setting menu for allowing the player to select either the first half pattern or the second half pattern is displayed on the liquid crystal display device 50. It may be displayed and selected by the player.

  Specifically, when the player operates the effect button 16 to display the pseudo-continuous number setting menu 600 on the liquid crystal display device 50 as shown in FIG. 31, and the player sets the maximum pseudo-continuous number of times to three. As shown in FIG. 35, the pseudo-continuous type setting menu 601 is displayed, and one of “first half type”, “second half type”, and “no designation” is selected and determined by the player operating the effect button 16. When the player selects “second half type”, for example, in the case of the production pattern (O), the pseudo ream (2) is removed, and when the player selects “first half type”, for example, In the case of the production pattern (O), the pseudo ream (3) is excluded. If the player selects “not specified” or if there is no decision operation by the player even after a predetermined time has elapsed, the current setting is taken over as it is.

As a result, when the player selects the “first half type”, the fact that the pseudo-ream (3) does not readily occur after the pseudo-ream (2) is likely to indicate that there is a high possibility of shifting to the development 4. When the pseudo-ream (2) is shorter than the pseudo-ream (3), it is suggested that there is a high possibility of shifting to the development 3. If the player chooses the “second half type”, it seems that there is a high possibility that the pseudo-ream (1) is not likely to be generated from the pseudo-ream (1), and that there is a high possibility of shifting to the development 4. This suggests that the possibility of shifting to 3 has decreased.
When the player sets the maximum number of pseudo-reams to two, the player sets the timing of the pseudo-ream (2) effect display in the effect pattern (O) as shown in FIG. 34 (b). , Immediately before reach, or immediately after pseudo-ream (1).

  Thus, in the modification of 2nd Embodiment shown in FIG.34, FIG.35, in a series of effect images containing a pseudo | simulation series, one continuous effect image (image based on the effect pattern containing a pseudo-continuous effect). By performing a plurality of types of special pseudo-continuous effect display according to the type of specific effect image display that is excluded from (for example, the pseudo-continuous (2) or pseudo-continuous (3) effect display in the temporary stop state), for example, , If you want to know the development destination of the production early, select "first half type", if you want to know the development destination of the production later, select the "second half type" It becomes possible to give interest.

[Third Embodiment]
Next, a third embodiment of the present invention will be described. In addition, in the pachinko gaming machine 1 of the third embodiment, the same members as those in the pachinko gaming machine 1 of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. The pachinko gaming machine 1 of the third embodiment is the same as the structure of the pachinko gaming machine 1 in the first embodiment, but part of the processing executed by the sub CPU 201 of the sub control circuit 200 is different. Specifically, in the third embodiment, the effect pattern determination process shown in FIG. 19 in the first embodiment is different.

[Direction pattern determination processing]
FIG. 36 is a flowchart showing an effect pattern determination process in the third embodiment.
In the effect pattern determination process in the third embodiment, in step S240, as in the first embodiment, the sub CPU 201 performs a process of extracting an effect pattern corresponding to the variation pattern designated by the variation pattern designation command. If this process ends, the process moves to a step S241.

In step S241, processing for determining whether or not to execute a pseudo-continuous effect is performed. In this process, as in the first embodiment, if the sub CPU 201 determines that the pseudo-continuous designation data is included in the variation pattern designation command, the process proceeds to step S242. When it is not determined that the pseudo-continuous designation data is included, the processing from step S246 to step S248 is performed as in the first embodiment, and this subroutine is terminated.
In step S242, as in the first embodiment, the sub CPU 201 performs a process of extracting an effect pattern including pseudo-continuations, that is, a pseudo-continuous effect pattern, from the effect patterns extracted in step S241. If this process ends, the process moves to a step S243.

  In step S243, a process of determining a pseudo continuous effect pattern is performed. In this process, as in the first embodiment, when the number of pseudo continuous effect patterns extracted in step S242 is one, the sub CPU 201 determines that pattern as an effect pattern in the identification symbol game. Performs a process of selecting one pseudo-continuous effect pattern by random lottery or the like and determining that pattern as an effect pattern in the identification symbol game. If this process ends, the process moves to a step S331.

  In step S331, pseudo continuous effect pattern setting processing is performed. In this process, the sub CPU 201 performs a process of storing, in the work RAM 203, the pseudo continuous effect pattern determined in step S243 or a pseudo continuous effect pattern obtained by changing a part of the pseudo continuous effect pattern. Details of this processing will be described later. If this process ends, the process moves to a step S332.

  In step S332, pseudo continuous reliability notification effect setting processing is performed. In this process, the sub CPU 201 performs a process of storing effect data for notifying the reliability according to the number of pseudo-continuations in the program ROM 202. Details of this processing will be described later. When this process is completed, the pseudo-continuous number notification effect setting process of step S245 is performed as in the first embodiment, and when this process is completed, this subroutine is terminated. Note that this pseudo-continuous number notification effect setting process can be omitted.

[Pseudo-continuous effect pattern setting process]
Next, the pseudo continuous effect pattern setting process will be described with reference to FIG.
As shown in FIG. 37, in step S341, a pseudo continuous number lottery is performed. In this process, the sub CPU 201 performs a process of determining the number of pseudo consecutive times by random lottery in the range of 2 to 4. That is, in the second embodiment, the player sets the number of pseudo-continuations in advance, but in the third embodiment, the gaming machine side sets the number of pseudo-continuations. If this process ends, the process moves to a step S342.

  In step S342, the sub CPU 201 performs a process of determining whether or not the number of pseudo consecutive times in the pseudo continuous effect pattern determined in step S243 is larger than the number of pseudo continuous numbers determined in step S341. If it is determined that the value is large, the process proceeds to step S343. If it is not determined that the value is large, the process proceeds to step S344.

  In step S343, a process of changing the pseudo-continuous effect is performed. In this process, the sub CPU 201, as in step S322 in the second embodiment, converts a plurality of pseudo-series of a predetermined combination into one pseudo-series in the plurality of pseudo-series included in the pseudo-series effect pattern determined in step S243. Process to be integrated into. That is, the process of changing the data of the pseudo-continuous effect pattern so as to reduce the number of pseudo-continuous effects in the pseudo-continuous effect pattern determined in step S243 to the number of pseudo-continuous effects determined in step S341 is performed. In this process, the sub CPU 201 stores data of the pseudo-continuous number before the change and the pseudo-continuous number after the change in a predetermined storage area of the work RAM 203. If this process ends, the process moves to a step S344.

  In step S344, pseudo continuous effect pattern setting processing is performed. In this processing, the sub CPU 201 performs processing for storing the pseudo continuous effect pattern determined in step S243 or the pseudo continuous effect pattern changed in step S343 in the work RAM 203. That is, when the changed pseudo-continuous number of times data is stored in a predetermined storage area of the work RAM 203, the pseudo continuous effect pattern changed in step S343 is stored in the work RAM 203, and the predetermined storage of the work RAM 203 is stored. When the data of the number of pseudo-continuous times after the change is not stored in the area, the pseudo-continuous effect pattern determined in step S243 is stored in the work RAM 203. When this process is finished, this subroutine is finished.

[Pseudo continuous reliability notification effect setting processing]
Next, the pseudo continuous reliability notification effect setting process will be described with reference to FIG.
In step S351, it is determined whether or not the pseudo continuous effect pattern stored in the work RAM 203 includes a pattern in which a plurality of pseudo continuous patterns are integrated. In this process, the sub CPU 201 determines whether or not the data of the changed pseudo-continuous number is stored in a predetermined storage area of the work RAM 203. If it is determined that the data is stored, the process proceeds to step S352. If it is not determined that it is stored, the process proceeds to step S354.

  In step S352, an effect determination lottery is performed. In this process, the sub CPU 201 performs a process of determining whether or not to perform the pseudo continuous reliability notification effect by random number lottery. If this process ends, the process moves to a step S353.

  In step S353, pseudo-reliability notification effect setting is performed. In this process, when the sub CPU 201 determines to perform the effect determination lottery in step S352, the sub CPU 201 refers to the first pseudo continuous reliability notification effect determination table stored in the program ROM 202, and determines a predetermined value in the work RAM 203. Based on the post-change pseudo-continuous count stored in the storage area, the pseudo-continuous reliability notification effect is determined, and the data is stored in the work RAM 203. Then, the display control process in step S224 in FIG. 17 provides an effect of displaying the reliability information for each pseudo-run on the liquid crystal display device 50. When this process is finished, this subroutine is finished.

  In step S354, an effect determination lottery is performed. In this process, the sub CPU 201 performs a process of determining whether or not to perform the pseudo continuous reliability notification effect by random number lottery. Here, the winning probability of the effect determination lottery in step S352 is set higher than the winning probability of the effect determination lottery in this process. If this process ends, the process moves to a step S355.

  In step S355, pseudo-reliability notification effect setting is performed. In this process, when the sub CPU 201 determines to perform the effect determination lottery in step S <b> 352, the sub CPU 201 refers to the second pseudo continuous reliability notification effect determination table stored in the program ROM 202, and stores a predetermined value in the work RAM 203. Based on the number of pseudo-continuations stored in the storage area, a pseudo-continuous reliability notification effect is determined, and processing for storing the data in the work RAM 203 is performed. Then, the display control process in step S224 in FIG. 17 provides an effect of displaying the reliability information for each pseudo-run on the liquid crystal display device 50. When this process is finished, this subroutine is finished.

  The table for determining the first pseudo-continuous reliability notification effect is provided corresponding to each effect pattern including at least three or more pseudo-reams, and the pseudo-reams to be displayed on the liquid crystal display device 50 for the number of pseudo-reams after the change. The reliability values of 1 to 4 are stored in association with each other. Specifically, for example, the pseudo-reliability notification effect determination table shown in FIG. 39A is associated with the effect pattern O of FIG.

  As shown in FIG. 39 (b), the second pseudo-reliability notification effect determination table is the reliability of pseudo-ream 1 to pseudo-ream 4 displayed on the liquid crystal display device 50 in the effect patterns G to O of FIG. The degree value is associated and stored.

  25, when the number of pseudo-continuous operations is not changed (NO in step S351 in FIG. 38), the second pseudo-continuous reliability notification effect determination table shown in FIG. 39B is referred to. For this reason, the liquid crystal display device 50 displays “quasi-continuous 1: 5%, pseudo-continuous 2: 10%, pseudo-continuous 3: 30%, pseudo-continuous 4: 60%” and reliability information for each pseudo-continuous count. . When the number of pseudo-continuous operations is changed to 3 in the effect pattern O of FIG. 25, the table for determining the first pseudo-continuous reliability notification effect shown in FIG. The pseudo-ream 1: 5%, pseudo-ream 2: 10%, pseudo-ream 3: 60%, pseudo-ream 4: 50% "and reliability information for each number of pseudo-reams are displayed. When the number of pseudo consecutive times is changed to 2 in the effect pattern O of FIG. 25, the table for determining the first pseudo continuous reliability notification effect shown in FIG. The pseudo-ream 1: 5%, pseudo-ream 2: 60%, pseudo-ream 3: 30%, pseudo-ream 4: 50% "and reliability information for each number of pseudo-reams are displayed.

  Thus, when the pseudo continuous effect pattern is changed in step S343, the reliability corresponding to the final pseudo continuous pattern in the changed pseudo continuous pattern is set to the highest numerical value, and step When the pseudo continuous effect pattern is not changed in S343, the reliability corresponding to the final pseudo continuous effect is set to the highest numerical value. Note that the number of other pseudo-continuations can be set as appropriate. According to the present embodiment, when the number of pseudo consecutive times is 2 as in the production pattern L, or when the number of pseudo continuous times is changed from 4 to 2 in the effect pattern O, the number of pseudo continuous times is 3 times. Alternatively, since it is not four times, the reliability when the number of pseudo-continuations is three or four is set lower than that when the number of pseudo-continuations is two. This makes it possible to give an impression to the player that it is more advantageous that the number of pseudo consecutive times is not three or four.

[Description of production screen]
FIG. 40 is an explanatory diagram illustrating an example of a pseudo-reliability notification effect screen displayed on the liquid crystal display device 50 according to the third embodiment. FIG. 40 shows an example in which the pseudo continuous number is changed from 4 times to 2 times in the effect pattern O of FIG.

  FIG. 40 (a) is an example of an effect screen showing the state after the start of variation in the three identification symbols 52 for effects, and when the first start port 414a or the second start port 414b is won, the liquid crystal display device The three identification symbols 52 for effect displayed in the 50 display areas 51 are variably displayed. Then, as shown in FIG. 40 (b), when the temporary display is stopped in a stop display mode (for example, a serial number such as 1, 2, 3) which is a condition for generating the pseudo-continuous, the rectangular display area 51 A right triangle piece image 501a is arranged on the right side.

  Furthermore, when the three identification symbols 52 for presentation are in a temporary stop state, the number of pseudo-continuations of “pseudo-continuous 1: 5%, pseudo-continuous 2: 60%, pseudo-continuous 3: 30%, pseudo-continuous 4: 50%”. The reliability information 701 for each item is displayed, and the identification symbol 52 changes again as shown in FIG. 40C in a state where the display of the piece image 501a and the reliability information 701 is maintained. A player who sees this desires to end the pseudo-ream 2 and move to reach without continuing the pseudo-ream.

  The display of the reliability information 701 is erased after a predetermined time, as shown in FIG. 41 (a), and thereafter, the three identification symbols 52 for presentation are temporarily stopped in a stop display mode which is a condition for generating a pseudo-continuity. In this case, a right triangle piece image 501b is arranged at the lower left of the display area 51. At this point, the player can easily grasp that the pseudo-ream has been performed twice by displaying the piece images 501a and 501b and the two piece images 501. Thereafter, after reaching the reach state, the stage shifts to the development effect, and the three identification symbols 52 for the effect stop, so that the player can identify whether or not it is a big hit.

  Immediately after the three identification symbols 52 for production re-variate from the temporarily stopped state, as shown in FIG. 41 (b), the character information 702 that "the one that is not continuous is hot" is displayed above the display area 51. By displaying, it may be suggested again that the player is more likely to win a big hit if the pseudo-ream does not continue.

  As described above, according to the third embodiment configured as described above, there is a case where the probability of transition to an advantageous gaming state is higher when the number of consecutive pseudo-realistic display is smaller, and the transition to the advantageous gaming state may occur. Information on the probability is notified by the information notification means in a mode corresponding to the number of times of the pseudo-continuous effect display, so the probability of transition to an advantageous gaming state is not constant depending on the number of times of the pseudo-continuous effect display, On the other hand, it is possible to provide a gaming machine that can maintain the player's interest in the pseudo-continuous effect display while maintaining the expectation for the transition from the pseudo-continuous effect display to an advantageous gaming state.

  Further, according to the third embodiment, before the pseudo-continuous effect display is performed, the player is taught the correspondence relationship between the continuous number of the pseudo-continuous effect display and the transition probability to an advantageous gaming state, By performing the pseudo-continuous effect display based on the correspondence, it becomes possible to maintain the player's interest in the pseudo-continuous effect display.

  Further, according to the third embodiment, after the pseudo-continuous effect display is performed for the player, the correspondence relationship between the continuous number of the pseudo-continuous effect display and the transition probability to an advantageous gaming state is taught, By performing the pseudo-continuous effect display based on the correspondence, it becomes possible to maintain the player's interest in the pseudo-continuous effect display.

  Although the third embodiment has been described above, the third embodiment is not limited to the configuration described above. For example, in the case of the effect pattern O in FIG. 25, when the number of pseudo-continuations is changed from 4 times to 2 times, as shown in FIGS. 42 (a) to 42 (d), As shown in FIG. 42 (e), after performing an effect of returning time such as a rewind effect, the state may be changed from the pseudo-continuous twice state to the reach state. In other words, the image data ROM 211 includes image data for displaying the patterns shown in FIGS. 42B to 42F as image data of the pseudo sequence obtained by integrating the pseudo sequence (2) and the pseudo sequence (3). Also good. As a result, it is possible to improve again the interest that has been reduced by performing up to three pseudo-continuations by the rewind effect. In this way, it becomes possible to maintain the player's interest in the pseudo-continuous effect display.

[Fourth Embodiment]
Next, a fourth embodiment of the present invention will be described. In addition, in the pachinko gaming machine 1 of the fourth embodiment, the same members as those in the pachinko gaming machine 1 of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. The pachinko gaming machine 1 of the fourth embodiment is the same as the structure of the pachinko gaming machine 1 in the first embodiment, but part of the processing executed by the sub CPU 201 of the sub control circuit 200 is different. Specifically, in the fourth embodiment, the command analysis process shown in FIG. 18 and the effect pattern determination process shown in FIG. 19 in the first embodiment are different.

[Command analysis processing]
FIG. 43 is a flowchart showing command analysis processing in the fourth embodiment.
The command analysis processing in the fourth embodiment is obtained by adding processing in steps S356 to S358 described later to the command analysis processing in the first embodiment shown in FIG.
In FIG. 43, the processing from step S230 to step S236 is the same as the command analysis processing of the first embodiment shown in FIG. If it is determined in step S234 that the sub CPU 201 has not received the derived symbol designation command (NO in step S234), the process proceeds to step S356.

  In step S356, it is determined whether or not a symbol stop command has been received. In this processing, the sub CPU 201 determines whether or not the symbol received command is included in the command received from the main control circuit 100 as a result of the analysis in step S231, and determines that the symbol stopped command is included. In step S357, the process proceeds to step S357. If it is determined that the symbol stop command is not included, the process proceeds to step S236.

  In step S357, processing for setting data for effect display to the effect of the end of pseudo-continuation in the work RAM 203 is performed. In this process, the sub CPU 201 determines whether or not the pseudo-ream is performed in the effect display immediately before receiving the symbol stop command, and only when it is determined that the pseudo-ream is performed, the display area of the liquid crystal display device 50 Data for causing the work RAM 203 to store the effect display of the fact that the pseudo-continuous end is displayed in 51 is performed. As the effect display indicating the end of the pseudo-continuation, a pseudo-continuation end effect image 710 made up of character information “pseudo-continuation revival?” Shown in FIG. Then, by the display control process in step S224 in FIG. 17, while the three identification symbols 52 for effects are stopped in the liquid crystal display device 50, the effect display indicating that the quasi-continuous end has been performed is performed. When this process ends, the process moves to a step S358.

  In step S358, the sub CPU 201 performs other processing corresponding to the symbol stop command. When this process is finished, this subroutine is finished.

[Direction pattern determination processing]
FIG. 44 is a flowchart showing effect pattern determination processing in the fourth embodiment.
In the effect pattern determination process in the fourth embodiment, the pseudo-number-of-times notification effect setting process in step S245 in the effect pattern determination process in the first embodiment shown in FIG. 19 is different. Since other processes are the same as the effect pattern determination process of the first embodiment, the description thereof is omitted.

[Pseudo consecutive number notification effect setting processing]
Next, the pseudo continuous effect pattern setting process will be described with reference to FIG.
As shown in FIG. 45, in step S361, a process is performed to determine whether or not the number of holds is two or more. In this process, the sub CPU 201 stores data in at least two storage areas of the variation pattern storage area (1) to the variation pattern storage area (2) in the variation pattern storage area (1) to the variation pattern storage area (4). It is determined whether or not it is stored. If it is determined that the reserved number is two or more, the process proceeds to step S362. If it is not determined that the reserved number is two or more, the process proceeds to step S368.

  In step S362, a process is performed to determine whether or not the previous production pattern includes a pseudo-ream and is a reach-less loss. In this processing, the sub CPU 201 is based on the data stored in the variation pattern storage area (1) to the variation pattern storage area (4), and based on the data in the previous variation pattern storage area. It is determined whether or not the set effect pattern is a pattern that includes a pseudo-ream and loses without reaching. Here, if it is determined that the loss includes a quasi-ream and does not reach, the process proceeds to step S363, and if it is not determined that the loss includes a quasi-ream and does not reach, the process proceeds to step S368. Move.

  In step S363, a pseudo-continuous restoration lottery is performed. In this process, the sub CPU 201 determines whether or not to perform a pseudo-continuous reviving effect in which the pseudo-ream executed in the previous effect pattern is succeeded to the pseudo-ream included in the effect pattern set in the process of step S244. Random lottery for determination. In this random number lottery, the winning probability may be changed according to the jackpot reliability of the effect pattern set in the process of step S244. For example, the winning probability may be increased as the performance pattern has a higher degree of jackpot reliability. As a result, the player sees the quasi-ream effect revived while enhancing the sense of expectation for the big hit by looking at the quasi-revival effect. If this process ends, the process moves to a step S364.

  In step S364, the sub CPU performs a process of determining whether or not the result of the random number lottery executed in step S363 is a win. If it is determined that the win is selected, the sub CPU moves the process to step S365 and determines that it is a win. If not, the process proceeds to step S368.

  In step S <b> 365, the sub CPU 201 performs processing for storing the number of pseudo-continuations in the pseudo-continuous pattern included in the previous effect pattern in a predetermined storage area of the work RAM 203. If this process ends, the process moves to a step S366.

  In step S <b> 366, the sub CPU 201 performs processing for setting the pseudo-continuous restoration notification data in the work RAM 203. The quasi-continuous revival notification data is displayed at the start of the variation of the identification symbol 52 and is displayed to the player as if the last re-variation display in the quasi-continuous production of the previous identification symbol 52 has been restored. This is data for executing the effect display to be shown. This effect display shows the pseudo information (pseudo consecutive number) in the variation of the character information (suggested image 712) “improvement image 712” and “× 1” of the previous identification symbol 52 shown in FIG. 46 (f). Information 56) applies. The number of pseudo-continuous additions shown in FIG. 46 (f) is set within the range of the pseudo-continuous number in the pseudo-continuous effect pattern set in the process of step S244. If this process ends, the process moves to a step S367.

  In step S <b> 367, the sub CPU 201 performs processing for setting pseudo continuous number of times notification data for pseudo continuous restoration in the work RAM 203. The pseudo-continuous number notification data for pseudo-continuous restoration refers to the pseudo-continuous number information (pseudo-continuous number information 56 (FIG. 46) when the pseudo-continuous effect pattern set in the process of step S244 is performed. See))). The quasi-continuous number is a value obtained by adding the quasi-continuous number executed in the variation of the preceding identification symbol 52 to the quasi-continuous number in the pseudo-continuous effect pattern. Then, by the display control process in step S224 in FIG. 17, every time the three identification symbols 52 for effects are temporarily stopped in the liquid crystal display device 50, an effect of displaying the quasi-continuous number of times is performed. For example, if the number of quasi-continuous executions performed in the previous change of the identification symbol 52 is one, “× 2” at the timing when the first temporary stop is performed according to the quasi-continuous effect pattern set in the process of step S244. At the timing of the second temporary stop, an effect display “+1” is performed to the original number of pseudo-continuations, such as “× 3”. When this process is finished, this subroutine is finished.

  In step S <b> 368, the sub CPU 201 performs processing for setting the pseudo continuous number notification data in the work RAM 203. The quasi-continuous number notification data indicates the quasi-continuous number (pseudo-continuous number information 56 (see FIG. 46)) at the timing of performing the quasi-continuous when the effect by the pseudo-continuous effect pattern set in the process of step S244 is executed. It is data to make it. Then, by the display control process in step S224 in FIG. 17, every time the three identification symbols 52 for effects are temporarily stopped in the liquid crystal display device 50, an effect of displaying the quasi-continuous number of times is performed. For example, according to the pseudo continuous effect pattern set in the process of step S244, an effect display such as “× 1” at the timing of the first temporary stop and “× 2” at the timing of the second temporary stop is performed. Done. That is, there is addition in the process of step S367, but there is no addition in the process of step S368. When this process is finished, this subroutine is finished.

[Description of production screen]
FIG. 46 is an explanatory diagram showing the transition of the effect screen displayed on the liquid crystal display device 50 according to the fourth embodiment. In FIG. 46, there are two starting opening prizes (entering the first starting opening 414a or the second starting opening 414b) during the fluctuation of the three identification symbols 52 for production, both of which are pseudo-continuous. As an example, In the production based on the first start opening prize, one pseudo run is performed, and in the production based on the second start opening prize, three pseudo runs are performed.

  If there are two start opening winnings while the three identification symbols 52 for presentation displayed in the display area 51 of the liquid crystal display device 50 are variably displayed, as shown in FIG. 46 (a), the display area Two reserved symbols 55 are displayed at 51. Then, as shown in FIG. 46 (b), after the three identification symbols 52 for production are in the stop display state, as shown in FIG. Variation display of the two identification symbols 52 is started. After a predetermined time has elapsed since the start of the variable display, as shown in FIG. 46D, the three identification symbols 52 are temporarily stopped, and the pseudo-continuous count information 56 for informing the pseudo-continuous count of “× 1”. Is displayed in the display area 51. Thereafter, as shown in FIG. 46E, the three identification symbols 52 are changed again. At this time, the display of the pseudo continuous number information 56 of “× 1” is maintained. Then, after the predetermined time has elapsed, as shown in FIG. 46 (f), the three identification symbols 52 are in a stopped display state.

  At this time, since the stop display mode of the identification symbol 52 is not a stop display mode in which consecutive numbers such as “123” and “234” are continuous, the player knows that the pseudo-ream has ended. When the three identification symbols 52 are stopped, the pseudo continuous number information 56 disappears from the display area 51 and a pseudo continuous end effect image 710 of “pseudo continuous revival?” Is displayed. Furthermore, the player can clearly see that the pseudo-ream has ended by viewing the pseudo-ream end effect image 710 of “pseudo-revival? As described above, the stop display mode of the identification symbol 52 is an effect display that is not a stop display mode in which consecutive numbers such as “123” and “234” are continuous, or a pseudo-continuous end effect image “pseudo continuous revival?”. The effect display 710 is an example of a pseudo-continuous end effect display.

  As shown in FIG. 46 (f), after the three identification symbols 52 are in the stop display state, as shown in FIG. 46 (g), as shown in FIG. Fluctuation display is started. Here, simultaneously with the start of the variable display of the identification symbol 52, the pseudo-continuous number information 56 of “× 1” is displayed in the display area 51 and the suggestion image 712 of “pseudo-continuous two times addition” is displayed. That is, as shown in FIG. 46 (f), the derivation display based on the first start winning is completed, and the derivation display based on the second start winning is started, and at the same time, the pseudo consecutive number of “× 1” Since the information 56 and the suggestion image 712 of “addition of two pseudo-reams” are displayed, it appears to the player as if the pseudo-ream effects have been restored. In addition, the suggestion image 712 notifies the player that the pseudo-ream will continue two more times.

  Thereafter, the suggestion image 712 disappears from the display area 51, and after a predetermined time has elapsed, as shown in FIG. 46 (h), the three identification symbols 52 are temporarily stopped and the pseudo-continuous count information 56 of “× 2”. Is displayed in the display area 51. Thereafter, as shown in FIG. 46 (i), the display of fluctuation of the three identification symbols 52 is started, and after a predetermined time has elapsed, as shown in FIG. 46 (j), the three identification symbols 52 are temporarily stopped. At the same time, pseudo-continuous number information 56 of “× 3” is displayed in the display area 51. Thereafter, as shown in FIG. 46 (k), when the variable display of the three identification symbols 52 is started, a suggestion image 712 of “pseudo-continuous one-time addition” is displayed. The suggestion image 712 notifies the player that the pseudo-ream will continue once more. In the example shown in FIG. 46, three pseudo-continuations are performed based on the effect pattern, so that the additional display by the suggestion image 712 is possible up to a total of three times. The display of the suggestion image 712 can be divided into a plurality of displays as long as it is up to three times as shown in FIG. This makes it possible for the player to expect that the number of pseudo-reams will be added each time a pseudo-ream continues.

  Further, after the predetermined time has elapsed, as shown in FIG. 46 (l), the three identification symbols 52 are temporarily stopped, and the pseudo continuous number information 56 for informing the pseudo continuous number of “× 4” is displayed in the display area 51. Is displayed. Thereafter, as shown in FIG. 46 (m), when the variable display of the three identification symbols 52 is started, the reach state is reached as shown in FIG. 46 (n) after a predetermined time has elapsed. At this point, the player knows that the pseudo-ream has ended. Thus, the effect display in which the identification symbol 52 is in the reach display mode is an example of the pseudo-continuous effect display. Then, after performing the reach effect and the development effect, as shown in FIG. 46 (o), the three identification symbols 52 are in the stop display state.

  According to the fourth embodiment configured as described above, in the pseudo-continuous effect display, when a predetermined condition (two or more reserved balls are present and the pseudo-continuous effect is continuous) is satisfied, After the continuous end effect display is performed, the pseudo continuous revival effect display is performed. As a result, it is possible to give a joy that the pseudo-continuous effect display has been restored to the player who has been disappointed that the pseudo-continuous effect display has ended once by performing the pseudo-continuous effect display. Even if the pseudo-continuous effect display is once performed, it is possible to give a sense of expectation that the pseudo-continuous effect display will be revived. It is possible to provide a gaming machine that can maintain a sense of expectation for a transition from a pseudo-continuous effect display to an advantageous gaming state while maintaining it.

  Further, according to the fourth embodiment, the pre-read result of the information stored in the hold storage means (variation pattern storage area (1) to fluctuation pattern storage area (4) of the work RAM 203) is stored in the hold storage means. When performing pseudo-continuous effect display in the symbol variation display based on the previous lottery result, the last in the pseudo-continuous effect display based on the previous lottery result in the symbol variation display based on the next lottery result stored in the holding storage means Can be reinstated. Thus, by performing the pseudo-continuous end effect display and the pseudo-continuous effect display, it becomes possible to perform continuous pseudo-continuous effect display, and once the pseudo-continuous end effect display is performed, the player who is disappointed On the other hand, it is possible to provide the joy of reviving the pseudo-ream effect display in a timely manner.

  According to the fourth embodiment, the pseudo-continuous effect display is restored, and the suggestion image indicating the number of re-variable display in the pseudo-continuous effect display based on the next lottery result is displayed. It is possible to make the player feel as if the number of variable displays is added. In this way, it is possible to provide the player with the pleasure of adding the number of pseudo-reams.

  Although the fourth embodiment has been described above, the fourth embodiment is not limited to the configuration described above. For example, according to the above-described fourth embodiment, the pattern of losing without the reach and including the pseudo ream is only the effect pattern G (see FIG. 25), and the maximum number of pseudo reams is the effect pattern O (see FIG. 25). ) 4 times. For this reason, the display of the maximum number in the suggestion image 712 in the fourth embodiment is “× 5”. However, the effect pattern is not limited to the one described above, and includes, for example, an effect pattern in which the identification symbol 52 stops after reaching the pseudo-ream 1 and the pseudo-ream 2 after reaching the start of fluctuation of the identification symbol 52. May be. In this case, the display of the maximum number in the suggestion image 712 is “× 6”.

  Also, according to the fourth embodiment described above, as shown in FIG. 46 (f), after the three identification symbols 52 for production are in the stop display state, as shown in FIG. Although the pseudo continuous number information 56 of “× 1” is displayed in the display area 51, the pseudo continuous number information 56 of “× 2” may be displayed in the display area 51 instead. That is, as shown in FIG. 46 (g), the case where the identification symbol 52 is stopped may be handled as if it is a part of a pseudo-ream. Further, after that, every time the temporary stop display state by the pseudo-continuous effect is entered, the display may be performed such that “× 3”, “× 4”,. . This makes it possible for the player to feel as if the pseudo-continuous effect has continued for a long time from the derivation display of the previous identification symbol 52.

  In addition, when the number of holdings is 3, the first holding is two pseudo-continuous, the second holding is no pseudo-continuing, and the third holding is three pseudo-continuing, the identification pattern 52 based on the second holding Is displayed in the display area 51 at the start of the fluctuation, and at the start of the fluctuation of the identification symbol 52 based on the third hold, together with the pseudo-number information 56 of “× 2”. , The suggestion image 712 may be displayed as “addition of three pseudo-reams”.

  In step S362 shown in FIG. 45 in the above-described fourth embodiment, the condition that the pseudo-ream is included is removed, and the pseudo-revival lottery is performed even when the pseudo-ream is not performed in the effect in the previous derivation display. To be done. Then, when the pseudo-revival lottery is won, as shown in FIG. 46 (f), after the three identification symbols 52 for production are in the stop display state, as shown in FIG. The pseudo continuous number information 56 of “× 1” may be displayed in the display area 51. Thereby, it becomes possible to make the player feel the start of the fluctuation of the identification symbol 52 as if the pseudo-continuous production started.

  In addition, when it ends by the pseudo-ream (3), at the start of the change of the identification symbol 52 by the next hold, the pseudo-revival effect display is performed and the effect display of the pseudo-ream (2) is performed to simulate one time. On the condition that the number of consecutive times decreases, it is possible to provide an effect display in which the pseudo-ream is restored and continued.

  A display mode is also conceivable in which the player participation game is played, the number of times of addition is accumulated, and the number of times of addition is subtracted when the pseudo-continuous effect display by prefetching is restored.

[Fifth Embodiment]
Next, a fifth embodiment of the present invention will be described.
In the fifth embodiment, a part of the process is added to the command analysis process shown in FIG. 18 in the first embodiment shown in FIGS. In addition, about the member or process same as the member or process in 1st Embodiment shown in FIGS. 1-18, the same code | symbol or step number is attached | subjected and detailed description is abbreviate | omitted. In addition, the special winning opening residual ball monitoring process shown in step S66 of FIG. 10 will also be described in detail.

[Monitoring of residual ball in big prize award]
FIG. 47 is a flowchart showing the flow of the special winning opening residual ball monitoring process executed in the first embodiment and the fifth embodiment of the present invention.

  First, as shown in FIG. 47, it is determined whether or not the control state flag is a value (05) indicating monitoring of a winning ball remaining ball (step S1061), and whether or not the waiting time timer is “0”. Is determined (step S1062). In this process, when the main CPU 101 determines that the control state flag is a value indicating monitoring of the winning ball remaining ball and the waiting time timer is “0”, the process proceeds to step S1063. On the other hand, if the main CPU 101 does not determine that the value indicates monitoring of the winning ball residual ball, or if it does not determine that the waiting time timer is “0”, the main CPU 101 ends this subroutine. To do.

  In step S1063, it is determined whether or not a specific area has passed. In this process, the main CPU 101 determines whether or not there is a predetermined detection signal supplied from the count sensor 113 between the opening of the special winning opening 418 and the execution of this process, and based on this. If it is determined that the specific area has passed, the process proceeds to step S1064. If it is not determined that the specific area has passed, the process proceeds to step S1067.

  In step S1064, it is determined whether or not the number of times that the special winning opening is opened is equal to or greater than a set number (for example, 10 or 16). In this process, if the main CPU 101 determines that the value read from the big winning opening opening number counter is equal to or larger than the set number, the process moves to step S1067, where the large winning opening is opened more than the set number. If NO is determined, the process proceeds to step S1065.

  In step S <b> 1065, the main CPU 101 executes a process of setting a value (06) indicating the big winning opening reopening waiting time management as the control state flag. Then, the main CPU 101 executes processing for setting a time corresponding to the interval between rounds in the waiting time timer (step S1066). When this process is finished, this subroutine is finished.

  On the other hand, in step S1067, the main CPU 101 executes a process of setting a value (07) indicating a big hit end interval as a control state flag. Then, the main CPU 101 executes processing for setting the time corresponding to the jackpot end interval in the storage area of the main RAM 103 that functions as a waiting time timer (step S1068). Further, the main CPU 101 executes a process of setting a jackpot end interval command in a predetermined storage area of the main RAM 103 (step S1069). The jackpot end interval command is transmitted to the sub-control circuit 200 by the process of the main CPU 101 in step S14. The sub-control circuit 200 can recognize that the jackpot end interval is started by receiving the jackpot end interval command. When the process of step S1069 ends, this subroutine ends.

  Next, command analysis processing in the fifth embodiment will be described.

[Command analysis processing]
The command analysis process in the fifth embodiment shown in FIG. 48 is obtained by adding the processes in steps S1236 to S1241 to the command analysis process in the first embodiment shown in FIG.

In FIG. 48, steps S231 to S236 are the same as those in the first embodiment shown in FIG. If the sub CPU 201 determines in step S234 that the command received from the main control circuit 100 does not include a derived symbol designation command, the process proceeds to step S1237. If the process of step S235 ends, the process proceeds to step S1236.
In step S1236, the sub CPU 201 performs a change count storage process. This process will be described later. When this process is finished, this subroutine is finished.

In step S1237, it is determined whether or not a shot ball command has been received. In this process, if the sub CPU 201 determines that the firing ball command has been received from the main control circuit 100 as a result of the analysis in step S231, the process moves to step S1238, and the firing ball command is not included. If so, the process moves to step S1240.
In step S1238, the sub CPU 201 performs a shot ball number storage process. This process will be described later. When this process is finished, this subroutine is finished.

  In step S1240, it is determined whether or not a jackpot end interval command has been received. In this process, if the sub CPU 201 determines that the jackpot end interval command has been received from the main control circuit 100 as a result of the analysis in step S231, it moves the process to step S1241 and receives the jackpot end interval command. If not, the process moves to step S1243.

  In step S1241, an ending setting process at the end of the big hit is performed. Although details of this process will be described later, the sub CPU 201 performs a process of storing data for instructing creation of an ending image at the end of the jackpot in the work RAM 203. If this process ends, the process moves to a step S1242.

  In step S1242, the sub CPU 201 performs a process of stopping the timer started in the process of step S1248, which will be described later, and resetting (setting the timer value to 0). When this process is finished, this subroutine is finished.

  In step S1243, it is determined whether or not a jackpot end command has been received. In this process, if the sub CPU 201 determines that the jackpot end command has been received from the main control circuit 100 as a result of the analysis in step S231, the process proceeds to step S1244 and does not determine that the jackpot end command has been received. In that case, the process proceeds to step S1246.

  In step S1244, the sub CPU 201 performs processing for initializing the variation counter and the number of shot balls counter. If this process ends, the process moves to a step S1245.

  In step S1245, processing for turning off the variation count setting flag and the number of shot balls setting flag is performed. In this process, the sub CPU 201 stores a value for turning off the variation number setting flag and the firing ball number setting flag in a predetermined storage area of the work RAM 203 that functions as the variation number setting flag and the firing ball number setting flag. Do. When this process is finished, this subroutine is finished.

  In step S1246, processing for determining whether or not a gaming state command has been received is performed. In this process, if the sub CPU 201 determines that the gaming state command has been received from the main control circuit 100 as a result of the analysis in step S231, the process proceeds to step S1247 and does not determine that the gaming state command has been received. In that case, the process proceeds to step S237.

  In step S1247, the sub CPU 201 determines whether or not the value of the time reduction flag included in the game state command data is “1”, and determines that the value of the time reduction flag is “1” (time reduction state). In this case, the subroutine is terminated. If it is not determined that the value of the time reduction flag is “1” (in the case of a non-time reduction state), the process proceeds to step S1248.

  In step S1248, processing for starting a timer is performed. In this process, the sub CPU 201 performs a process of updating the predetermined storage area of the work RAM 203 that functions as a timer by adding the same value every predetermined time. That is, according to the fifth embodiment, after the game hall is opened, the timer is started when the first player launches a game ball, or when the game state shifts to the normal game state after the big hit game state ends. . When this process is finished, this subroutine is finished.

  In step S237, processing corresponding to the received other command is performed. In this processing, the sub CPU 201 performs processing corresponding to commands other than the variation pattern designation command and the derived symbol designation command. When this process is finished, this subroutine is finished.

[Variation count storage processing]
Next, the variation count storage process executed in step S1236 of FIG. 48 will be described with reference to FIG.

  In step S1250, it is determined whether or not the variation count setting flag is on. In this process, the sub CPU 201 determines whether or not a value to be turned on is stored in the storage area of the work RAM 203 that functions as the variation count setting flag, and when it is determined that the variation count setting flag is on. Ends this subroutine. If it is not determined that the variation count setting flag is on, the process proceeds to step S1251.

  In step S1251, processing for determining whether or not the timer is stopped is performed. In this process, the sub CPU 201 performs a process of determining whether or not the timer is in a stopped state, in other words, whether or not the timer has been started by the process of step S1248. If it is determined that the timer is stopped, this subroutine is terminated. If it is not determined that the timer is stopped, the process proceeds to step S1252.

  In step S1252, a process of adding “1” to the value of the variation counter is performed. In this process, the sub CPU 201 performs a process of adding +1 to the value stored in the storage area of the work RAM 203 that functions as a variation counter. In other words, the fluctuation number counter counts the number of fluctuations when the normal game state (low probability state and non-time-short state) is entered after the big hit game ends. If this process ends, the process moves to a step S1253.

  In step S1253, processing for determining whether or not the timer value has exceeded the set time is performed. In this process, if the sub CPU 201 determines that the value of the timer started in step S1245 has exceeded a set time (for example, 1 minute), it moves the process to step S1254 and does not determine that the set number of balls has been exceeded. In this case, this subroutine is terminated.

  In step S1254, processing for storing the number of fluctuations is performed. In this processing, the sub CPU 201 performs processing for storing the value counted by the variation counter in a predetermined storage area of the work RAM 203. If this process ends, the process moves to a step S1255.

  In step S1255, processing for turning on the variation count setting flag is performed. In this process, the sub CPU 201 performs a process of storing a value to be turned on in the storage area of the work RAM 203 that functions as a variation count setting flag. When this process is finished, this subroutine is finished.

[Launched ball number memory processing]
Next, the firing ball number storage process executed in step S1238 of FIG. 48 will be described with reference to FIG.

  In step S1260, a process is performed to determine whether or not the number-of-balls setting flag is on. In this process, the sub CPU 201 determines whether or not a value to be turned on is stored in the storage area of the work RAM 203 that functions as a firing ball number setting flag, and determines that the firing ball number setting flag is on. In this case, this subroutine is terminated. If it is not determined that the number of shot balls setting flag is on, the process proceeds to step S1261.

  In step S1261, it is determined whether or not the timer is stopped. In this process, the sub CPU 201 performs a process of determining whether or not the timer is in a stopped state, in other words, whether or not the timer has been started by the process of step S1248. If it is determined that the timer is stopped, the present subroutine is terminated. If it is not determined that the timer is stopped, the process proceeds to step S1262.

  In step S1262, a process of adding “1” to the value of the firing ball number counter is performed. In this process, the sub CPU 201 performs a process of adding +1 to the value stored in the storage area of the work RAM 203 that functions as a firing ball number counter. If this process ends, the process moves to a step S1263.

  In step S1263, processing for determining whether or not the timer value has exceeded the set time is performed. In this process, if the sub CPU 201 determines that the value of the timer started in step S1248 has exceeded a set time (for example, 1 minute), the sub CPU 201 moves the process to step S1264 and does not determine that the set number of balls has been exceeded. In this case, this subroutine is terminated. Note that the timer may be stopped when it is determined that the value of the timer started in step S1248 exceeds a set time (for example, 1 minute), and the timer may be reset in the process of step S1242.

  In step S1264, processing for storing the number of shot balls is performed. In this process, the sub CPU 201 performs a process of storing the value counted by the shot ball number counter in a predetermined storage area of the work RAM 203. If this process ends, the process moves to a step S1265.

  In step S1265, processing for turning on the number-of-balls setting flag is performed. In this process, the sub CPU 201 performs a process of storing a value to be turned on in the storage area of the work RAM 203 that functions as a shot ball number setting flag. When this process is finished, this subroutine is finished.

[Ending setting process]
Next, the ending setting process executed in step S1241 of FIG. 48 will be described with reference to FIG.

  In step S1271, the lottery ratio is set based on the number of fluctuations and the number of shot balls. In this processing, the sub CPU 201 obtains the number of times the number of shot balls fluctuates per 100 balls based on the number of times of change and the number of shot balls stored in the work RAM 203, and based on the result of the calculation, FIG. With reference to the ending determination table, processing for setting a range of random values used for lottery for determining the content of the ending display is performed. When the process of step S1271 is completed, the process proceeds to step S1272.

[Ending decision table]
FIG. 52 is an example of a table showing a range of random number values used for the lottery for determining the content of the ending display. According to the fifth embodiment, this table is used for determining the character color of “battle end” by lottery in the ending display shown in FIG. The character color of “battle end” is determined from any of blue, green, red, and rainbow colors.

  As shown in FIG. 52, when the number of changes is less than 5, the blue lottery probability is 70%, the green lottery probability is 20%, the red lottery probability is 10%, and the rainbow lottery probability is 0%. In this way, random numbers are distributed. When the number of fluctuations is 5 or more and less than 5.5, the blue lottery probability is 60%, the green lottery probability is 20%, the red lottery probability is 20%, and the rainbow lottery probability is 20%. Random numbers are distributed. When the number of fluctuations is 5.5 or more and less than 6, the blue lottery probability is 50%, the green lottery probability is 20%, the red lottery probability is 28%, and the rainbow lottery probability is 2%. Random numbers are distributed. When the number of changes is 6 or more, random numbers are distributed so that the blue lottery probability is 40%, the green lottery probability is 20%, the red lottery probability is 30%, and the rainbow lottery probability is 10%. It has been. In other words, in the normal gaming state, the pachinko gaming machine 1 that tends to win the first starting port 414a or the second starting port 414b has a red character in the “battle end” character color in the ending display shown in FIG. And rainbows are more likely to appear.

  Returning to FIG. 51, in step S1272, the sub CPU 201 performs a lottery process for determining the ending effect. If this process ends, the process moves to a step S1273.

  In step S1273, the sub CPU 201 determines a ending effect based on the lottery result, and performs a process of setting ending effect data in a predetermined storage area of the work RAM 203. Then, in the display control process of step S224 shown in FIG. 17, the sub CPU 201 selects the work image 203 in step S1273 from among a plurality of effect image display data “battle end” stored in the image data ROM 211. The data specified by the data set in is read out, an ending effect image is created, and the liquid crystal display device 50 performs effect display. When this process is finished, this subroutine is finished.

  That is, according to the fifth embodiment, when shifting from the big hit gaming state to the normal gaming state (non-time saving state), the ending is performed based on the number of changes in the set time (for example, 1 minute) from the start of the normal gaming state. In the case of transition from the big hit gaming state to the time saving state, the ending is determined based on the number of fluctuations in the set time (for example, 1 minute) after the time saving state ends and the normal gaming state starts. .

  As an initial value of the variation counter, a value obtained by subtracting the number of reserved pieces before the big hit gaming state ends may be set. For example, if there is a total of six hold information in the special figure 1 and special figure 2 before the big hit gaming state ends, the initial value of the variation counter may be set to “−6”. good. This makes it possible to match the value of the variation counter to the number of winnings to the first starting port 414a or the second starting port 414b after the end of the big hit gaming state, and more accurately the lottery for determining the ending It becomes possible to do.

[Description of production screen]
FIG. 53 is an explanatory diagram illustrating an example of an effect screen displayed on the liquid crystal display device 50 according to the fifth embodiment.

  FIG. 53A is an example of an effect screen displayed during the round game in the big hit gaming state, and the display area 51 of the liquid crystal display device 50 displays round number information 800 and characters 801a and 801b. Has been. According to the fifth embodiment, an effect image in which the character 801a and the character 801b fight during the round game is displayed, and the player is notified that the game will be in a high probability state after the big hit gaming state by winning the character 801a. Then, when the character 801a is defeated, the player is notified that the high probability state will not be entered after the big hit gaming state.

  53 (b) and 53 (c) show an ending screen after all the round games are finished, and character information 802 “battle end” is displayed. FIG. 53 (b) shows a case where the character 801a has won, and FIG. 53 (c) shows a case where the character 801a has been defeated. In FIG. 53 (b), when the character color of the character information 802 is “blue”, the player visually recognizes the character color, so that the pachinko gaming machine 1 in which he / she was playing is in the normal gaming state. It is possible to grasp that there is a tendency that it is relatively difficult to win a prize at the first start port 414a or the second start port 414b. Further, when the character color of the character information 802 is “green” or “red”, the player can play the first start port 414a or the second in the normal gaming state when the pachinko gaming machine 1 that the player has played is in the normal gaming state. It can be seen that the start opening 414b tends to win relatively easily. Further, in FIG. 53 (c), when the character color of the character information 802 is “rainbow”, the player is in the first start port 414a when the pachinko gaming machine 1 that he / she has played is in the normal gaming state. Or it turns out that it exists in the tendency which is easy to win a prize to the 2nd starting opening 414b.

  As a result, it is possible to give the player a chance to determine whether or not to continue the game after the end of the big hit gaming state or after the time saving state. For example, in FIG. 53B, when the character color of the character information 802 is “blue”, it is possible to give the player a sense of ending the game when the high probability state ends. . Further, when the ending is as shown in FIG. 53 (c), the player tends to win the first starting port 414a or the second starting port 414b, so that the player has an awareness of continuing the game. Is possible.

  As described above, according to the fifth embodiment configured as described above, the lottery means (main CPU 101) performs a lottery lottery in response to the start winning at the first start port 414a and the second start port 414b. In addition to displaying the effect image according to the result, the selected effect image display is made according to the relationship between the number of game balls fired after being initialized by the initialization means and the number of times the symbols are changed. Therefore, it becomes possible to provide the player with a new method of selecting the effect image display, and the monotony of the effect image display can be eliminated. Specifically, according to the fifth embodiment, by changing the color of a line (for example, character information 802 as a battle result) in the ending effect at the end of the big hit game, the pachinko gaming machine in the game is given to the player. It is possible to perform an effect display that suggests whether or not 1 tends to be a start winning prize. This makes it possible for the player to give information when selecting whether to end the game as it is.

  As mentioned above, although 5th Embodiment of this invention was described, the structure of 5th Embodiment of this invention is not restricted to what was mentioned above. For example, in the fifth embodiment described above, the number of changes is stored (step S1236 in FIG. 48), the number of shot balls is stored (step S1238 in FIG. 48), and the number of changes and the number of shot balls are initialized (step in FIG. 48). Although S1244) is performed in the sub-control circuit 200, these processes may be performed in the main control circuit 100.

  Specifically, the main CPU 101, for example, after the game hall is opened, the number of shot balls when the first player plays for a predetermined time (for example, 1 minute) and the number of fluctuations in the special figure 1 and special figure 2, Alternatively, the main RAM 103 stores the number of shot balls and the number of fluctuations in the special figure 1 and the special figure 2 when the player has played for a predetermined time (for example, 1 minute) in the normal gaming state after the end of the big hit gaming state. Then, in step S14 shown in FIG. 6, the number of shot balls and the number of fluctuations are transmitted to the sub-control circuit 200 as an ending effect designation command. After transmission, the main CPU 101 initializes the number of shot balls and the number of fluctuations.

  Receiving the ending effect designation command, the sub CPU 201 of the sub control circuit 200 determines the number of shot balls 100 based on the number of shot balls and the number of fluctuations included in the ending effect designation command in the command analysis process (step S222 in FIG. 17). The number of fluctuations in the sphere is calculated and stored in the work RAM 203. Then, at the end of the big hit game, the sub CPU 201 reads a line (for example, character information 802 as a battle result) corresponding to the number of fluctuations in the number of shot balls stored in the work RAM 203 from the image data ROM 211, and performs an ending effect. It is created and displayed on the liquid crystal display device 50.

  By configuring in this way, it is possible to perform an effect display that suggests whether or not the pachinko gaming machine 1 that is being played tends to win a start prize.

[Sixth Embodiment]
Next, a pachinko gaming machine 1 according to a sixth embodiment of the present invention will be described with reference to FIGS. In addition, about the member same as the member in 1st Embodiment shown in FIGS. 1-27, or the member of the same function, the same code | symbol is attached | subjected and detailed description is abbreviate | omitted. Moreover, about the process same as the process in 1st Embodiment shown in FIGS. 7-19, the same step number is attached | subjected and detailed description is abbreviate | omitted.

  FIG. 54 is a front view showing the configuration of the game board 40 according to the sixth embodiment of the present invention. As shown in FIG. 54, the pachinko gaming machine 1 according to the sixth embodiment of the present invention has a central accessory 430 instead of an accessory that constitutes the first starting port 414a (see FIG. 4). An ordinary electric accessory 415 is arranged on the lower right side of the game area 41. Furthermore, two special symbol display devices 421a and 421b are provided as the special symbol display device 421.

  The central accessory 430 includes a entrance 430a through which a game ball can enter, a first guide passage 430b having a first start entrance winning ball sensor 116a, and a second guide passage having a second start entrance winning ball sensor 116b. 430c, and a distribution member 431 that distributes a path along which the game ball that has passed through the entrance 430a travels to either the first guide path 430b or the second guide path 430c. The sorting member 431 has a function of alternately switching the first guide path 430b and the second guide path 430c every time a game ball passes. That is, the first guide path 430b and the second guide path 430c perform the same functions as the first start port 414a and the second start port 414b in the first embodiment. For convenience of the following description, an opening for receiving a game ball upstream of the first guide path 430b is referred to as a first start port 414a, and an opening for receiving a game ball upstream of the second guide path 430c is referred to as a second start port 414b. I will decide. That is, in the sixth embodiment, there are two second start ports 414b, but even if a game ball enters any of the second start ports 414b, the game ball remains in the second start port winning ball sensor 116b. Pass through. The special symbol display device 421a performs the derivation display of the first special symbol based on the start winning at the first starting port 414a. The special symbol display device 421b performs derivation display of the second special symbol based on the start winning at the second starting port 414b. For this reason, the first special symbol and the second special symbol can be changed simultaneously.

  Only the game balls that are driven into the right area of the game area 41 (so-called right-handed) can enter the second start opening 414b of the ordinary electric accessory 415.

  Since other configurations in the other game boards 40 are substantially the same as those in the first embodiment, detailed description thereof is omitted.

  In the first embodiment, as shown in FIGS. 20 (a) and 20 (b), there is a case where a special hit 1 lottery state is entered, but a special figure 2 lottery is entered. There is nothing. On the other hand, in the sixth embodiment, as shown in FIGS. 55 (a) and 55 (b), there is a case where the special hit 1 lottery and the special figure 2 lottery shift to the small hit gaming state.

  Further, in the first embodiment, there may be a time-short state after the end of the big hit gaming state, but in the sixth embodiment, in addition to that, only after the end of the small hit gaming state by the special drawing 1 lottery, It will be in a time-saving state until reaches a predetermined number of times. The state after the end of the small hit gaming state by the special figure 1 lottery will be referred to as a special short time state.

  In the special time reduction state, the fluctuation time of the special figure 2 is set shorter than the fluctuation time of the special figure 2 in the non-time reduction state. Specifically, in a non-time-short state, when the variation time of the variation pattern that is easy to be selected when the special drawing 1 lottery is lost and the variation time of the variation pattern that is easy to be selected when the special drawing 2 lottery is lost, The variation time in the special figure 2 lottery is set longer. On the other hand, in the special short-time state, the fluctuation time of the fluctuation pattern that is easy to be selected when the special figure 1 lottery is lost is the same as the fluctuation time of the fluctuation pattern that is easy to select when the special figure 2 lottery is lost. Is set. In addition, when it shifts from the special drawing 2 lottery to the small hit gaming state, after the small hit gaming state is finished, the previous gaming state is taken over without shifting to the special time saving state.

[System timer interrupt processing]
According to the sixth embodiment, the system timer interrupt process shown in FIG. 6 is executed as in the first embodiment. In the sixth embodiment, in the command output process (see FIG. 6) in step S14, Data indicating the value of a special short-time state change count counter, which will be described later, is supplied to the sub-control circuit 200.

[Big hit random number judgment table]
The jackpot random number determination table used in the sixth embodiment will be described with reference to FIG. In the sixth embodiment, as shown in FIG. 55A, the big hit random number determination table used for the big hit determination by the special drawing 1 lottery is the same as the big hit random number determination table in the first embodiment shown in FIG. You are using a table. On the other hand, in the sixth embodiment, the jackpot random number determination table (second start port) used for the jackpot determination by the special drawing 2 lottery is, as shown in FIG. 55 (b), the probability variation flag “0” (non-probability variation state). ), The big hit determination random number value “777-943” (width 167) is associated with the big hit determination value data, and the random number value other than this is associated with the loss determination value data. In the jackpot random number determination table (second starting port), when the probability variation flag is “1” (probability variation state), the jackpot determination random number value “777-1277” (width 500) is associated with the jackpot determination value data. Loss determination value data is associated with random numbers other than this. Thus, in the sixth embodiment, when winning in the second start port 414b in a non-probable change state, the probability of winning a big hit (hereinafter also referred to as a big hit probability) is 1/392, and the probability of winning a small hit ( Hereinafter, also referred to as a small hit probability) is 1/218. On the other hand, when winning in the second start port 414b in the probability variation state, the big hit probability is 1/131, and the small win is not won.

[Main control main processing]
Next, main control main processing executed by the main CPU 101 in the sixth embodiment will be described. In the main control main process of the sixth embodiment, the special symbol memory check process shown in FIG. 11 in the main control main process of the first embodiment, the special symbol display time management process shown in FIGS. 12 and 13, and the big hit shown in FIG. Part of the end interval process is different. Since other processes are the same in the first embodiment and the sixth embodiment, detailed description thereof is omitted.

[Special symbol memory check processing]
The special symbol memory check process of the sixth embodiment will be described with reference to FIG. Note that the same step numbers are assigned to the same processes as those in the special symbol memory check process shown in FIG. The special symbol memory check process of the sixth embodiment is obtained by adding processes of steps S82 to S87 described later to the special symbol memory check process of the first embodiment shown in FIG.

  In step S70, it is determined whether or not the control state flag is a value (00) indicating a special symbol storage check. In this process, if the main CPU 101 determines that the control state flag is a value (00) indicating the special symbol storage check, the process proceeds to step S82. On the other hand, when the main CPU 101 determines that the control state flag is not the value (00) indicating the special symbol storage check, the main CPU 101 ends the present subroutine.

  In step S82, a process is performed to determine whether or not the number of first start opening prizes held is "0". In this process, the main CPU 101 determines the presence / absence of data in the first special symbol start storage area (0) to the first special symbol start storage area (4) of the main RAM 103. The main CPU 101 determines that the start memory corresponding to the first special symbol is 0, that is, no data is stored in the first special symbol start storage area (0) to the first special symbol start storage area (4). If so, the process moves to step S71. On the other hand, when the start memory corresponding to the first special symbol is not 0, the main CPU 101 stores data in the first special symbol start storage area (0) to the first special symbol start storage area (4). If so, the process moves to step S78. The main CPU 101 performs the process of step S83 after the process of step S83.

  In step S83, a process of subtracting “1” from the first starting stored number is performed. In this process, the main CPU 101 performs a process of clearing data in the first special symbol start storage area (0) of the main RAM 103. If this process ends, the process moves to a step S84.

  In step S84, a special symbol storage area transfer process based on the first start opening winning is performed. In this process, the main CPU 101 uses the first special symbol start storage area (0) to the first special symbol start storage area (0) to the first special symbol start storage area (1) to the first special symbol start storage area (4) of the main RAM 103, respectively. 1 A special symbol start storage area (3) is shifted (stored). If this process ends, the process moves to a step S85.

  In step S85, a process of setting a value (01) indicating special symbol variation time management to the control state flag is performed. In this process, the main CPU 101 performs a process of setting a value (01) indicating special symbol variation time management to the control state flag. If this process ends, the process moves to a step S86. Further, the main CPU 101 generates a derived symbol designation command for determining a derived symbol (first identification symbol for production) corresponding to the first special symbol that the sub CPU 201 described later displays on the special symbol display device 421 in a stopped manner. And stored in a predetermined area of the main RAM 103. The main CPU 101 outputs this derived symbol designation command to the sub-control circuit 200 in step S14 shown in FIG. The sub CPU 201 of the sub control circuit 200 starts to display the derived symbol variation display based on the received derived symbol designation command.

  In step S86, a waiting time setting process is performed. In this process, the main CPU 101 performs a process of setting a variation time corresponding to the variation pattern of the special symbol determined in step S37 or step S46 shown in FIG. If this process ends, the process moves to a step S87.

  In step S87, processing for clearing the storage area used for the current variation is performed. In this process, the main CPU 101 performs a process of clearing the storage area of the main RAM 103 used for the current variable display. If this process ends, the process moves to a step S71.

  In step S71, a process of determining whether or not the number of reserved second start opening winnings is “0” is performed. In this process, the main CPU 101 determines the presence / absence of data in the second special symbol start storage area (0) to the second special symbol start storage area (4) of the main RAM 103. In the main CPU 101, the start memory corresponding to the second special symbol is “0”, that is, no data is stored in the second special symbol start storage area (0) to the second special symbol start storage area (4). If it is determined, the process proceeds to step S77. On the other hand, in the main CPU 101, the start memory corresponding to the second special symbol is not “0”, that is, data is stored in the second special symbol start storage area (0) to the second special symbol start storage area (4). If it is determined that there is, the process proceeds to step S72.

  In step S72, a process of subtracting “1” from the second starting stored number is performed. In this process, the main CPU 101 performs a process of clearing data in the second special symbol start storage area (0) of the main RAM 103. If this process ends, the process moves to a step S73.

  In step S73, a special symbol storage area transfer process based on the second start opening winning is performed. In this process, the main CPU 101 uses the second special symbol start storage area (0) to the second special symbol start storage area (0) to the second special symbol start storage area (1) to the second special symbol start storage area (4) of the main RAM 103, respectively. 2. Shift (store) the special symbol start storage area (3). If this process ends, the process moves to a step S74.

  In step S74, a process of setting a value (01) indicating special symbol variation time management to the control state flag is performed. In this process, the main CPU 101 performs a process of setting a value (01) indicating special symbol variation time management to the control state flag. If this process ends, the process moves to a step S75. In addition, the main CPU 101 generates a derived symbol designation command for the sub CPU 201 to be described later to determine a derived symbol corresponding to the second special symbol to be stopped and displayed on the special symbol display device 421 (an identification symbol for presentation). Stored in a predetermined area of the main RAM 103. The main CPU 101 outputs this derived symbol designation command to the sub-control circuit 200 in step S14 shown in FIG. The sub CPU 201 of the sub control circuit 200 starts to display the derived symbol variation display based on the received derived symbol designation command.

  In step S75, a waiting time setting process is performed. In this process, the main CPU 101 performs a process of setting a variation time corresponding to the variation pattern of the special symbol determined in step S37 or step S46 shown in FIG. If this process ends, the process moves to a step S76.

  In step S76, processing for clearing the storage area used for the current variation is performed. In this process, the main CPU 101 performs a process of clearing the storage area of the main RAM 103 used for the current variable display. When this process is finished, this subroutine is finished.

  In step S80, a demonstration display process is performed. In this process, the main CPU 101 performs a process of setting a demonstration display permission value in the main RAM 103. In addition, the main CPU 101 determines that the state in which the special symbol game start memory (the first special symbol start memory area or the second special symbol start memory area in which the random number value for hit determination is stored) is 0 for a predetermined time (for example, , 30 seconds), the value that permits execution of the demo display is set as the demo display permission value. When the demonstration display permission value is a predetermined value, the main CPU 101 sets a demonstration display command and supplies it to the sub control circuit 200. The sub-control circuit 200 performs a demonstration display on the liquid crystal display device 50 based on this demonstration display command. When this process is finished, this subroutine is finished.

  That is, in the first embodiment, the main CPU 101 preferentially digests the suspension of the special figure 2, whereas in the second embodiment, the main CPU 101 changes the special figure 1 and the special figure 2 at the same time. Is possible.

[Special symbol display time management process]
The special symbol display time management process of the sixth embodiment will be described with reference to FIG. In addition, about the process same as the process in the special symbol display time management process in 1st Embodiment shown in FIG. 12, 13, the same step number is attached | subjected and detailed description is abbreviate | omitted.
In FIG. 57, when the processes of steps S90 to S97 are completed, the process proceeds to step S1098.

  In step S1098, a process is performed to determine whether or not the special short-time state fluctuation count counter is “0”. In this process, the main CPU 101 determines whether or not the value of the special short-time state fluctuation count counter in the main RAM 103 is “0”. Here, the special time-short state change frequency counter indicates the number of times the special symbol is changed and stopped in the special time-short state. If the main CPU 101 determines that the value of the special time state change count counter is “0”, the main CPU 101 performs processing for storing a special time end command in a predetermined area of the main RAM 103 and ends this subroutine. The special short time end command is transmitted to the sub-control circuit 200 by the process of step S14 of the main CPU 101. If the main CPU 101 determines that the value of the second short-time state variation number counter is not “0”, the process proceeds to step S1099.

  In step S1099, a process of subtracting “1” from the special short-time state fluctuation count counter is performed. In this process, the main CPU 101 performs a process of subtracting “1” from the special short-time state fluctuation count counter in the main RAM 103. If this process ends, the process moves to a step S1100.

  In step S1100, a process is performed to determine whether or not the special short-time state fluctuation count counter is “0”. In this process, the main CPU 101 determines whether or not the value of the special short-time state fluctuation count counter in the main RAM 103 is “0”. If the main CPU 101 determines that the value of the special time-short state change count counter is “0”, the main CPU 101 moves to step S1101, and determines that the value of the special time-short state change count counter is not “0”. Ends this subroutine.

  In step S1101, a process of setting “0” in the special time reduction flag is performed. In this process, the main CPU 101 performs a process of setting “0” in the special time reduction flag stored in the main RAM 103. Here, the special short time flag is a flag that is stored in the main RAM 103 and indicates whether or not the special short time state is selected as the gaming state after the small hit gaming state by the special drawing 1 lottery. When it is “0”, it indicates that it is not in the special time reduction state (non-time reduction state), and when its value is “1”, it indicates that it is in the special time reduction state. In the process of step S56 shown in FIG. 9, the main CPU 101 generates game state data to be transmitted to the sub control circuit 200 according to the value of the special time reduction flag. When this process is finished, this subroutine is finished.

[Big hit end interval processing]
The jackpot end interval process of the sixth embodiment will be described with reference to FIG. The same steps as the jackpot end interval process in the first embodiment shown in FIG. 14 are denoted by the same step numbers, and detailed description thereof is omitted.
As shown in FIG. 18, when the processes of steps S110 to S117 are completed, the process proceeds to step S1120.

In step S1120, a special time reduction flag is set. In this process, the main CPU 101 sets a value for turning on the special time reduction flag when it is determined that the game is based on the symbol designation command determined in step S35 or step S44 shown in FIG. For example, a process of storing “1” in the main RAM 103 is performed. In the case where it is not determined that the winning is due to the special figure 1 lottery, a value for turning off the special time reduction flag, for example, “0” is stored in the main RAM 103. Further, the main CPU 101 performs processing for storing a special time reduction start command in a predetermined area of the main RAM 103. The special short time start command is transmitted to the sub control circuit 200 by the process of step S14 of the main CPU 101. In this process, the main CPU 101 does not turn on the special time reduction flag when the time reduction flag is on. If this process ends, the process moves to a step S118.
Thereafter, similarly to the first embodiment, the processes in steps S118 to S121 are performed, and when step S121 is completed, the process proceeds to step S1121.

  In step S1121, it is determined whether or not the special time reduction flag is “1”. In this process, the main CPU 101 determines whether or not the value of the special time reduction flag in the main RAM 103 is “1”. If the main CPU 101 determines that the value of the special time flag is “1”, the main CPU 101 proceeds to step S1122, and if it determines that the value of the special time flag is not “1”, the main CPU 101 ends this subroutine. To do.

  In step S <b> 1122, processing for setting the number of time reductions in the special time / short state change frequency counter is performed. In this processing, processing for setting the number of time reductions (for example, 30 times) in the special time state change frequency counter of the main RAM 103 is performed. When this process is finished, this subroutine is finished.

  Next, processing executed by the sub CPU 201 of the sub control circuit 200 in the sixth embodiment will be described. In the sixth embodiment, a part of the command analysis processing in the first embodiment shown in FIG. 18 is different.

[Command analysis processing]
The command analysis processing in the sixth embodiment shown in FIG. 59 is obtained by adding steps S1301 to S1304 to the command analysis processing in the first embodiment shown in FIG.
59, steps S231 to S235 are the same as the processing in the first embodiment shown in FIG. If the sub CPU 201 determines in step S234 that the command received from the main control circuit 100 does not include the derived symbol designation command, the process proceeds to step S1301.

  In step S1301, it is determined whether or not a special short time start command has been received. In this process, if the sub CPU 201 determines that the special time reduction start command has been received from the main control circuit 100 as a result of the analysis in step S231, the process proceeds to step S1302, and the special time reduction flag value data is stored. If it is not determined that it has been received, the process proceeds to step S1303.

  In step S1302, a process for displaying a message indicating that the special time is short is performed. In this processing, the sub CPU 201 stores data for displaying on the liquid crystal display device 50 that suggests that the special time is short (for example, character information “accelerating” in FIG. 60B) in the work RAM 203. Perform the process. When this process ends, the subroutine ends.

  In step S1303, it is determined whether or not a special short time end command has been received. In this process, if the sub CPU 201 determines that the special time shortening end command has been received from the main control circuit 100 as a result of the analysis in step S231, it moves the process to step S1304 and stores the data of the special time shortening flag value. If it is not determined that it has been received, the process proceeds to step S236.

  In step S1304, a process for terminating the display indicating that the special time is short is performed. In this process, the sub CPU 201 performs a process of causing the liquid crystal display device 50 to end display indicating that the special time is short (for example, character information “acceleration” in FIG. 60B). When this process ends, the subroutine ends.

  In step S236, processing corresponding to the received other command is performed. In this processing, the sub CPU 201 performs processing corresponding to commands other than the variation pattern designation command and the derived symbol designation command. When this process is finished, this subroutine is finished.

[Description of production screen]
FIG. 60 is an explanatory diagram illustrating an example of an effect screen displayed on the liquid crystal display device 50 according to the sixth embodiment.

FIG. 60A shows an example of the effect screen of the liquid crystal display device 50 displayed in the display area 51 of the liquid crystal display device 50 in the sixth embodiment. As shown in FIG. 60 (a), in the normal gaming state, in the display area 51, there are three identification symbols 52a for effects, three identification symbols 52b for effects, a reserved symbol 55a, and a reserved symbol 55b. , Is displayed. The identification symbol 52a derives and displays the result of the special figure 1 lottery, and the identification symbol 52b derives and displays the result of the special figure 2 lottery. The reserved symbols 55a indicate that the special figure 1 lottery is reserved, and a maximum of four symbols are displayed. The reserved symbols 55b indicate that the special figure 2 lottery is reserved, and a maximum of four symbols are displayed. The identification symbol 52a and the identification symbol 52b can be varied simultaneously. In the state where the reserved symbol 55a is displayed, when the next change is started after the changing identification symbol 52a is stopped, one reserved symbol 55a is deleted. Similarly, when the next change is started after the changing identification symbol 52b is stopped while the hold symbol 55b is displayed, one hold symbol 55b is deleted.
According to the sixth embodiment, in the normal gaming state, the variable display time of the first special symbol is set longer than the variable display time of the second special symbol. For this reason, there is a tendency that the holding of the second special symbol is less digested than the holding of the first special symbol.

  FIG. 60B is an example of an effect screen showing a stop display mode of the three identification symbols 52a for effect when the small hit is won by the first special figure lottery. In the sixth embodiment, when the small win is won by the first special drawing lottery, the central identification symbol 52a that is changing in the reach state is a special stop display mode indicating the small win. Thereafter, the game is shifted to the small hit gaming state, and an effect screen in the small hit gaming state is displayed on the liquid crystal display device 50. Even if it is during a small hit, if there is a holding symbol 55b corresponding to the special drawing 2 lottery, the derivation display by the three identification symbols 52b for effects is continued.

  FIG. 60 (c) is an explanatory diagram showing an example of an effect screen during special times. After the small hit game resulting from winning the first special drawing lottery is completed, the game shifts to a special short-time game state. In the special short-time gaming state, the liquid crystal display device 50 displays character information 58 indicating that the special time short is “accelerating” and character information 59 indicating the remaining fluctuation number of the special short-time gaming state. By looking at the character information 58 and 59, the player can grasp that the fluctuation time of the three identification symbols 52b in the case of the loss is shortened.

  When the special time reduction state ends, the special time reduction flag is set to “0” by the processing of step S1101 shown in FIG. 57, and the special time reduction state ends. At this time, if the time reduction flag is “0”, the gaming state shifts to the normal gaming state. Since the special time reduction flag is turned off in the time reduction state, the time reduction state and the special time reduction state are not executed simultaneously. For this reason, it does not shift to the time-saving state after the special time-saving state is completed.

  When the special time saving state is finished and the game state is shifted to the normal gaming state, the character information 58 and 59 are erased from the liquid crystal display device 50, and the display mode is returned to that shown in FIG.

  According to the sixth embodiment configured as described above, the time to change the identification symbol 52 based on the special drawing 2 lottery over a predetermined period, triggered by winning the transition to the small hit gaming state, By making it shorter than the variation time of the identification symbol 52 in the normal gaming state, the number of variations of the identification symbol 52 based on the special symbol 2 lottery can be increased. Thereby, for example, when all the data is stored in the eight start storage areas, in other words, when the start winning is made in a state where the hold is satisfied, the big win lottery by the start winning is not performed. However, according to the sixth embodiment, since the hold information corresponding to the special figure 2 is quickly digested, it is possible to reduce the start winning prize in which the big hit lottery as described above is not performed.

Moreover, since the special figure 1 and the special figure 2 can be simultaneously changed and the hold information of the special figure 1 and the hold information of the special figure 2 are alternately stored, the special figure 1 can be more efficiently used. It becomes possible to digest the fluctuation of the special symbol based on the hold information and the hold information of the special figure 2.
Thus, according to the sixth embodiment, since it is possible to obtain more jackpot lotteries, it is possible to widen the chance of shifting to the jackpot gaming state, and the player's expectation for the transition to the jackpot gaming state Can be increased.

  Although the sixth embodiment of the present invention has been described above, the configuration of the sixth embodiment of the present invention is not limited to the configuration described above. For example, in the above-described configuration, the shift to the special short-time state is triggered by the small win by special drawing 1 lottery, but the special short-time state is not shifted by the small win by special drawing 2 lottery. However, it is also possible to shift to the special short-time state when triggered by a small win by special drawing 2 lottery. In this case, since there is a possibility of a small hit in the time-short state, it may be shifted to the special time-short state after the time-short state ends. For example, in the sixth embodiment, when the small win is won when the number of time reductions is 90, the special time reduction state remains 20 times after the time reduction state ends. Therefore, the special time reduction may be given 20 times after the time reduction state ends.

  The effects described in the embodiments of the present invention are merely a list of the most preferable effects resulting from the present invention, and the effects of the present invention are limited to those described in the embodiments of the present invention. It is not a thing.

  Hereinafter, techniques related to the present invention will be additionally described.

[Appendix 1]
[Background technology]
In a conventional pachinko machine, when a game ball that rolls and flows into a starting prize opening provided on the game board is entered, a winning lottery is performed to shift to a game state advantageous to the player, When a plurality of symbols displayed on a display means such as a display device fluctuate and a winning lottery is won, an advantageous gaming state (so-called jackpot gaming state) triggered by a plurality of symbols stopping in a predetermined combination Migrate to
If a game ball enters the start winning opening while a plurality of symbols are changing on the display means, a winning lottery is performed, while the holding state is maintained until the plurality of symbols changing are stopped. Then, after the fluctuating symbols are stopped, the plurality of symbols are newly fluctuated and stopped based on the winning lottery already performed. The maximum number in the hold state is 4.

  On the other hand, in accordance with the lottery result, the display means displays an effect image or the like in accordance with the change or stop of the symbol, thereby enhancing the expectation of shifting to an advantageous gaming state. In addition, in order to increase this expectation, the symbol stop in the symbol fluctuation / stop is not stopped completely, but is temporarily stopped (the symbol is finely moved and not completely stopped). A so-called quasi-continuous effect display is performed in which the effect is continuously changed (changed again) from the stop state, and the effect is continuously displayed until the symbol is completely stopped.

  In Patent Document 1, there are three types of symbol variation patterns: no pseudo-ream, 1 pseudo-ream, 2 pseudo-reams, 3 pseudo-reams, and 4 pseudo-reams. It is described that the rate at which a high-level reach effect is executed increases.

[Prior art documents]
[Patent Literature]
[Patent Document 1] JP-A-2006-5721

[Summary of Invention]
[Problems to be solved by the invention]
However, in such a pseudo-ream effect display, various types of pseudo-ream effects are often repeatedly performed, and in some cases, the same effects are continuously performed and the effects may overlap. Also, it may be unclear where the pseudo-ream production started and where it ended, and the greater the number of pseudo-reams, the higher the expectation of jackpots. Is fading.

  An object of this invention is to provide the gaming machine which solves the above-mentioned problem.

[Means for solving problems]
In order to achieve the above object, the present invention has the following configuration.

(1) A game area (game area 41) in which a game ball rolls and flows down, and a start winning opening (first start port 414a, second start port 414b) in which the game ball can enter the game area. A game board (game board 40) provided with
Lottery means (main CPU 101, processes in steps S34 and S43 in FIG. 8) for performing a lottery for shifting to a gaming state advantageous to the player, with the winning at the start winning opening,
A symbol display means (liquid crystal display device 50) for performing variable display and stop display of a plurality of symbols (three identification symbols 52);
In response to the game ball entering the start winning opening, a plurality of symbols are variably displayed, and the plurality of symbols variably displayed according to the lottery result of the lottery means are stopped and displayed in a predetermined combination. Design display control means (sub CPU 201, processing in steps S234 and S235 in FIG. 18),
The symbol display control means includes:
After temporarily displaying a plurality of fluctuating symbols, the control is performed at least once to perform fluctuating display, so that one continuous effect image (a quasi-continuous effect image, a pseudo image in FIG. 25) is displayed. While performing control (sub CPU 201, processing in step S224 in FIG. 17, processing in steps S243 and S244 in FIG. 19) for displaying the reams 1 to 4),
Control (display of piece images 501a to 501d) of the number of times of revariation suggestion (display of piece images 501a to 501d) according to the number of times of performing control of revariable display (number of pseudo-continuous operations) (sub CPU 201, processing in step S224 in FIG. 17, step S245 in FIG. 19) (2) is performed separately from the display of the continuous effect image.

  According to (1), the re-variation number suggesting effect display (display of piece images 501a to 501d) is continuously performed according to the number of times the re-variable display is controlled (pseudo continuous number of times). By performing the display separately from the above, it is possible to display the relationship between the continuous effect image display and the number of re-variable display in an easy-to-understand manner for the player. Thereby, it is possible to improve the effect of increasing the expectation of the original pseudo-ream for the player, that is, the expectation of jackpot increases as the number of pseudo-reams increases.

  (2) In (1), when the predetermined condition is satisfied, the symbol display control means displays the re-variation number suggesting effect display as a special image display (display of piece images 501a and 501b in FIG. 27G). A gaming machine characterized by performing control to switch to).

  According to (2), a special condition that the color of the re-variation number suggesting effect display (piece image 501) is changed in a predetermined condition, for example, when the effect develops after reaching the reach from the pseudo continuous image, etc. By switching to image display, the player expects a big hit expectation as the number of pseudo-reams increases, maintaining the effect of the original pseudo-ream for the player, and the player for the transition to an advantageous game state by the development effect It is possible to further increase the sense of expectation.

  (3) In (1) and (2), when the predetermined condition is satisfied, the symbol display control means displays an expectation suggestion effect display that suggests an expectation degree of transition to an advantageous state (FIG. 26 (e ) In the piece image 502 of “”, a display indicating “reliability is 60% if reaching here”).

  According to (3), by performing the expectation suggestion effect display indicating the expectation degree of the transition to the advantageous state, the player guesses how much the expectation degree for the transition to the advantageous state is increased. It is possible to further increase the player's expectation for the transition to an advantageous state.

[Effect of the invention]
ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the game machine which can maintain the effect which raises the expectation by an original pseudo | simulation series for a player.

[Appendix 2]
[Background technology]
In a conventional pachinko machine, when a game ball that rolls and flows into a starting prize opening provided on the game board is entered, a winning lottery is performed to shift to a game state advantageous to the player, When a plurality of symbols displayed on a display means such as a display device fluctuate and a winning lottery is won, an advantageous gaming state (so-called jackpot gaming state) triggered by a plurality of symbols stopping in a predetermined combination Migrate to
If a game ball enters the start winning opening while a plurality of symbols are changing on the display means, a winning lottery is performed, while the holding state is maintained until the plurality of symbols changing are stopped. Then, after the fluctuating symbols are stopped, the plurality of symbols are newly fluctuated and stopped based on the winning lottery already performed. The maximum number in the hold state is 4.

  On the other hand, in accordance with the lottery result, the display means displays an effect image or the like in accordance with the change or stop of the symbol, thereby enhancing the expectation of shifting to an advantageous gaming state. In addition, in order to increase this expectation, the symbol stop in the symbol fluctuation / stop is not stopped completely, but is temporarily stopped (the symbol is finely moved and not completely stopped). A so-called quasi-continuous effect display is performed in which effect change is performed from the stopped state (re-change) and effect display is continuously performed until the symbol is completely stopped.

  In Patent Document 1, there are three types of symbol variation patterns: no pseudo-ream, 1 pseudo-ream, 2 pseudo-reams, 3 pseudo-reams, and 4 pseudo-reams. It is described that the rate at which a high-level reach effect is executed increases.

[Prior art documents]
[Patent Literature]
[Patent Document 1] JP-A-2006-5721

[Summary of Invention]
[Problems to be solved by the invention]
However, even in such effect display by the pseudo-ream, if the game is repeatedly performed, the player can read a certain amount of effect pattern and easily lose interest. Therefore, it is desired to provide a gaming machine that can maintain the player's interest in the effect display by the pseudo-ream while maintaining the expectation for the transition from the pseudo-ream to an advantageous game state.

  An object of this invention is to provide the gaming machine which solves the above-mentioned problem.

[Means for solving problems]
In order to achieve the above object, the present invention has the following configuration.

(1) A game area (game area 41) in which a game ball rolls and flows down, and a start winning opening (first start port 414a, second start port 414b) in which the game ball can enter the game area. A game board (game board 40) provided with
Lottery means (main CPU 101, processes in steps S34 and S43 in FIG. 8) for performing a lottery for shifting to a gaming state advantageous to the player, with the winning at the start winning opening,
A symbol display means (liquid crystal display device 50) for performing variable display and stop display of a plurality of symbols (three identification symbols 52);
In response to the game ball entering the start winning opening, a plurality of symbols are variably displayed, and the plurality of symbols variably displayed according to the lottery result of the lottery means are stopped and displayed in a predetermined combination. Symbol display control means (sub CPU 201, processing in steps S234 and S235 in FIG. 18),
Effect image display data storage means (image data ROM 211) for storing a plurality of types of effect image display data;
An operation means (production button 16) that can be operated by the player,
The symbol display control means includes:
One temporary effect image (pseudo-continuous effect image, FIG. 25) is displayed in response to performing a control for performing at least one re-variation display for performing a variable display after temporarily displaying a plurality of symbols that have been displayed in a variable manner. Perform control to display pseudo ream 1-pseudo ream 4)
The effect image display data storage means stores effect image display data (image data of each of the pseudo-continuous 1 to the pseudo-continuous 4) corresponding to one re-variable display,
The symbol display control means includes:
Control of normal pseudo-continuous effect display for displaying one continuous effect image by connecting one effect image display data corresponding to one re-variable display for the number of times of re-variable display (sub CPU 201 in FIG. 17 Processing in step S224, processing in steps S243 and S244 in FIG. 30),
Except for a specific effect image display included in the one continuous effect image, a special pseudo-continuous effect display control that displays an effect image that reduces the number of re-variable displays (the processes of steps S322 and S244 in FIG. 30) )When,
Control that displays either a normal pseudo-continuous effect display or a special pseudo-continuous effect display according to the operation of the operation means by the player (sub CPU 201, processing in step S224 in FIG. 17, step S321 in FIG. 30, A game machine characterized by further performing the processing of S244.

  According to (1), a normal pseudo-continuous effect display is performed by the player's operation, or a special pseudo-continuous effect display with a smaller number of re-variable display (pseudo-continuous number) than the normal pseudo-continuous effect display. Since it is possible to select whether or not to perform, it is not possible to display a pseudo-continuous effect prepared in advance by the gaming machine, but to display a pseudo-continuous effect that can increase the expectation by the player himself It becomes possible. Accordingly, it is possible to maintain a sense of expectation for the transition from the pseudo-ream to an advantageous game state while maintaining the player's interest in the effect display by the pseudo-ream.

  (2) In (1), the symbol display control means has a plurality of types of special pseudo-continuous effect displays according to the number of specific effect image displays excluded from the one continuous effect image (FIG. 32, FIG. 33) is controlled (sub CPU 201, processing in step S300 in FIG. 28) to display a selection screen (pseudo continuous number setting menu in FIG. 31) selected by the player operating the operating means. To play.

  According to (2), according to the number of specific effect image displays excluded from one continuous effect image, the number of re-variable display (pseudo continuous number) in the special pseudo-continuous effect display can be set. Therefore, it is possible to select the number of variable display times in the pseudo-continuous effect display by operating the operation means by the player. For example, in the case where an effect image of four pseudo-continuations is included in one continuous effect image, by removing one of the specific effect image displays (for example, pseudo-continuation (2)), one The continuous effect image becomes the pseudo-continuous 3 times, and by removing two of the specific effect image displays (for example, the pseudo-ream (2) and the pseudo-ream (3)), one continuous effect image becomes the pseudo-ream. 2 times. In this way, since the player can select the number of times of the pseudo-ream, it is possible to maintain the player's interest in the effect display by the pseudo-ream and to maintain the expectation for the transition from the pseudo-ream to an advantageous gaming state. become.

  (3) In (1), the symbol display control means includes a plurality of types of special pseudo-continuous effect displays corresponding to the types of specific effect image displays excluded from the one continuous effect image (see FIG. 34). The game machine is characterized in that control is performed to display a selection screen (pseudo-continuous number setting menu in FIG. 35) that is selected by the player operating the operating means.

  According to (3), the display pattern in the special pseudo-continuous effect display can be changed according to the type of the specific effect image display excluded from one continuous effect image. By operation, it becomes possible to select a display pattern in the pseudo continuous effect display. For example, in the case where an effect image of four pseudo-continuations is included in one continuous effect image, three pseudo-continuations are performed except for one specific effect image display (for example, pseudo-continuation (2)). Alternatively, the player can select whether to display one of the other effect image displays (for example, the pseudo-ream (3)), or three pseudo-reams. In this way, since the display pattern in the pseudo-continuous effect display preferred by the player can be selected, the player's interest in the effect display by the pseudo-ream is maintained, and the expectation for the transition from the pseudo-ream to an advantageous gaming state is expected. Can be maintained.

[Effect of the invention]
ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to maintain the expectation with respect to the transition from a pseudo | simulation series to an advantageous game state, maintaining a player's interest with respect to the effect display by a pseudo | simulation series.

[Appendix 3]
[Background technology]
In a conventional pachinko machine, when a game ball that rolls and flows into a starting prize opening provided on the game board is entered, a winning lottery is performed to shift to a game state advantageous to the player, When a plurality of symbols displayed on a display means such as a display device fluctuate and a winning lottery is won, an advantageous gaming state (so-called jackpot gaming state) triggered by a plurality of symbols stopping in a predetermined combination Migrate to
If a game ball enters the start winning opening while a plurality of symbols are changing on the display means, a winning lottery is performed, while the holding state is maintained until the plurality of symbols changing are stopped. Then, after the fluctuating symbols are stopped, the plurality of symbols are newly fluctuated and stopped based on the winning lottery already performed. The maximum number in the hold state is 4.

  On the other hand, in accordance with the lottery result, the display means displays an effect image or the like in accordance with the change or stop of the symbol, thereby enhancing the expectation of shifting to an advantageous gaming state. In addition, in order to increase this expectation, the symbol stop in the symbol fluctuation / stop is not stopped completely, but is temporarily stopped (the symbol is finely moved and not completely stopped). A so-called quasi-continuous effect display is performed in which effect change is performed from the stopped state (re-change) and effect display is continuously performed until the symbol is completely stopped.

  In Patent Document 1, there are three types of symbol variation patterns: no pseudo-ream, 1 pseudo-ream, 2 pseudo-reams, 3 pseudo-reams, and 4 pseudo-reams. It is described that the rate at which a high-level reach effect is executed increases.

[Prior art documents]
[Patent Literature]
[Patent Document 1] JP-A-2006-5721

[Summary of Invention]
[Problems to be solved by the invention]
However, in such effect display by pseudo-ream, the relationship between the number of pseudo-reams and the expectation of jackpot is constant, and when the number of pseudo-reams is small, the expectation of transition to an advantageous gaming state is also reduced. Eventually, it is easy to lose interest in the pseudo-continuous effect display. Therefore, it is desired to provide a gaming machine that can maintain the player's interest in the effect display by the pseudo-ream while maintaining the expectation for the transition from the pseudo-ream to an advantageous game state.

  An object of this invention is to provide the gaming machine which solves the above-mentioned problem.

[Means for solving problems]
In order to achieve the above object, the present invention has the following configuration.

(1) A game area (game area 41) in which a game ball rolls and flows down, and a start winning opening (first start port 414a, second start port 414b) in which the game ball can enter the game area. A game board (game board 40) provided with
Lottery means (main CPU 101, processes in steps S34 and S43 in FIG. 8) for performing a lottery for shifting to a gaming state advantageous to the player, with the winning at the start winning opening,
A symbol display means (liquid crystal display device 50) for performing variable display and stop display of a plurality of symbols;
In response to the game ball entering the start winning opening, a plurality of symbols are variably displayed, and the plurality of symbols variably displayed according to the lottery result of the lottery means are stopped and displayed in a predetermined combination. Symbol display control means (sub CPU 201, processing in steps S234 and S235 in FIG. 18),
Effect image display data storage means (image data ROM 211) for storing a plurality of types of effect image display data,
The symbol display control means performs one continuous control in response to performing at least one re-variable display for performing variable display after temporarily stopping display of a plurality of symbols variably displayed by the symbol display control means. Control to display an effect image (pseudo sequence effect image, pseudo sequence 1 to pseudo sequence 4 in FIG. 25),
The effect image display data storage means stores effect image display data (image data of each of the pseudo-continuous 1 to the pseudo-continuous 4) corresponding to one re-variable display,
The symbol display control means controls the quasi-continuous effect display (sub-display) that displays one continuous effect image by connecting one effect image display data corresponding to one re-change display for the number of re-change displays. CPU 201, processing in step S224 in FIG. 17, processing in steps S243 and S244 in FIG.
Correspondence between the continuous number of re-variable display and the probability of transition to an advantageous gaming state, so that the probability of transition to an advantageous gaming state may be higher when the number of consecutive times of re-variable display in the pseudo-continuous effect display is small Correspondence storage means (program ROM 202, table for determining pseudo-reliability notification effect in FIG. 39) for storing the relationship;
When it is determined to perform the pseudo-continuous effect display, the transition probability to the advantageous gaming state is read from the correspondence relationship storage means for each consecutive number of re-variable display in the pseudo-continuous effect display, and the advantage is obtained at a predetermined timing. Information notification means (liquid crystal display device 50) for notifying information on the probability of transition to a different gaming state in a manner corresponding to each successive number of re-variable display in the pseudo-continuous effect display. Gaming machine.

  According to (1), the probability of transition to an advantageous gaming state is not constant depending on the number of re-variable displays, and the probability of transition to an advantageous gaming state is smaller when the number of re-variable displays in the pseudo-continuous effect display is smaller. Since the information regarding the transition probability to the advantageous gaming state is notified by the information notification means in a manner corresponding to the number of continuous re-variable displays, there is an advantageous re-change for the player. It becomes possible to inform the number of times of display. Accordingly, it is possible to provide a gaming machine that can maintain the player's interest in the pseudo-continuous effect display while maintaining the expectation for the transition from the pseudo-continuous effect display to an advantageous gaming state.

  (2) In (1), the information notification means has an advantageous game as a predetermined timing at a timing (for example, a temporary stop state, FIG. 40 (b)) before the symbols are variably displayed on the symbol display means. A gaming machine characterized by notifying information on a probability of transition to a state.

  According to (2), before the pseudo-continuous effect display is performed, the player is taught the correspondence between the continuous number of re-variable display in the pseudo-continuous effect display and the transition probability to an advantageous gaming state. Then, by performing the pseudo-continuous effect display based on the correspondence, the player's interest in the pseudo-continuous effect display is maintained.

  (3) In (1), the information notifying means, as a predetermined timing, is a timing after the symbol display means stops and displays the symbol (for example, when starting re-variation from the temporarily stopped state, FIG. 40 (c) ) And informing information regarding the probability of transition to an advantageous gaming state.

  According to (3), after the pseudo-continuous effect display is performed to the player, the correspondence between the continuous number of re-variable display in the pseudo-continuous effect display and the transition probability to an advantageous gaming state is taught. Then, by performing the pseudo-continuous effect display based on the correspondence, the player's interest in the pseudo-continuous effect display is maintained.

[Effect of the invention]
According to the present invention, it is possible to provide a gaming machine capable of maintaining the player's interest in the pseudo-continuous effect display and maintaining the expectation for the transition from the pseudo-continuous effect display to an advantageous gaming state. .

[Appendix 4]
[Background technology]
In a conventional pachinko machine, when a game ball that rolls and flows into a starting prize opening provided on the game board is entered, a winning lottery is performed to shift to a game state advantageous to the player, When a plurality of symbols displayed on a display means such as a display device fluctuate and a winning lottery is won, an advantageous gaming state (so-called jackpot gaming state) triggered by a plurality of symbols stopping in a predetermined combination Migrate to
If a game ball enters the start winning opening while a plurality of symbols are changing on the display means, a winning lottery is performed, while the holding state is maintained until the plurality of symbols changing are stopped. Then, after the fluctuating symbols are stopped, the plurality of symbols are newly fluctuated and stopped based on the winning lottery already performed. The maximum number in the hold state is 4.

  On the other hand, in accordance with the lottery result, the display means displays an effect image or the like in accordance with the change or stop of the symbol, thereby enhancing the expectation of shifting to an advantageous gaming state. In addition, in order to increase this expectation, the symbol stop in the symbol fluctuation / stop is not stopped completely, but is temporarily stopped (the symbol is finely moved and not completely stopped). There is an effect display called a so-called quasi-ream that performs change from the stop state (re-change) and continuously displays the effect until the symbol is completely stopped.

  In Patent Document 1, there are three types of symbol variation patterns: no pseudo-ream, 1 pseudo-ream, 2 pseudo-reams, 3 pseudo-reams, 4 pseudo-reams. It is described that the rate at which a high-level reach effect is executed increases.

[Prior art documents]
[Patent Literature]
[Patent Document 1] JP-A-2006-5721

[Summary of Invention]
[Problems to be solved by the invention]
However, in such an effect display by the pseudo-ream, the relationship between the number of pseudo-reams and the jackpot expectation degree is a constant pattern, and if the number of pseudo-reams is small, the expectation of the transition to an advantageous gaming state is also expected. It becomes thin and it is easy to lose interest in the pseudo-continuous effect display. Therefore, it is desired to provide a gaming machine that can maintain the player's interest in the effect display by the pseudo-ream while maintaining the expectation for the transition from the pseudo-ream to an advantageous game state.

  An object of this invention is to provide the gaming machine which solves the above-mentioned problem.

[Means for solving problems]
In order to achieve the above object, the present invention has the following configuration.

(1) There is a game area (game area 41) where the game ball rolls and flows down, and a start winning opening (first start port 414a, second start port 414b) in which the game ball can enter the game area. A game board (game board 40) provided with
Lottery means (main CPU 101, processes in steps S34 and S43 in FIG. 8) for performing a lottery for shifting to a gaming state advantageous to the player, with the winning at the start winning opening,
A symbol display means (liquid crystal display device 50) for performing variable display and stop display of a plurality of symbols;
In response to the game ball entering the start winning opening, a plurality of symbols are variably displayed, and the plurality of symbols variably displayed according to the lottery result of the lottery means are stopped and displayed in a predetermined combination. Symbol display control means (sub CPU 201, processing in steps S234 and S235 in FIG. 18),
Effect image display data storage means (image data ROM 211) for storing a plurality of types of effect image display data,
The symbol display control means performs one continuous control in response to performing at least one re-variable display for performing variable display after temporarily stopping display of a plurality of symbols variably displayed by the symbol display control means. Control to display an effect image (pseudo sequence effect image, pseudo sequence 1 to pseudo sequence 4 in FIG. 25),
The effect image display data storage means stores effect image display data (image data of each of the pseudo-continuous 1 to the pseudo-continuous 4) corresponding to one re-variable display,
The symbol display control means includes:
Control of pseudo-continuous effect display for displaying one continuous effect image by connecting one effect image display data corresponding to one re-variable display for the number of times of re-variable display (sub CPU 201, step S224 in FIG. 17) Process, steps S243 and S244 in FIG. 30),
In the pseudo continuous effect display, control of the pseudo continuous end effect display for displaying the effect image corresponding to the end of the re-variable display for the number of times (sub CPU 201, processing in step S357 in FIG. 43);
When the predetermined condition is satisfied, after the pseudo-continuous effect display, the pseudo continuous-resurrection effect display control for restoring the last re-variable display in the pseudo-continuous effect display (sub CPU 201, processing in step S245 in FIG. 44) ) And the game machine.

  According to (1), in the pseudo-continuous effect display, when the predetermined condition is satisfied, the pseudo-continuous effect display is performed after the pseudo-continuous effect display is performed, and therefore, the pseudo-continuous effect display is once performed. It is possible to give the joy that the pseudo-continuous effect display has been restored to the player who is disappointed at the end by performing the pseudo-continuous effect display, and the pseudo-continuous effect display is once performed. Even so, it is possible to give a sense of expectation that the pseudo-continuous effect display will be revived. In this way, it is possible to provide a gaming machine capable of maintaining a sense of expectation for the transition from the pseudo-continuous effect display to an advantageous gaming state while maintaining interest in the pseudo-continuous effect display for the player. Become.

  (2) In (1), information related to a lottery result of the lottery means triggered by a game ball entering the start winning opening while the symbol is variably displayed on the symbol display means. A holding storage unit (a variation pattern storage area (0) to a variation pattern storage area (4) of the work RAM 203) for storing and holding the variable display according to the lottery result is provided, and the symbol display control unit When the number of lottery results stored in the storage means becomes plural, the information stored in the hold storage means is pre-read before execution of the variable display according to the lottery result, and the lottery stored in the hold storage means When the pseudo-continuous effect display is performed in the symbol variation display based on the result, the pseudo-continuous effect display is performed in the symbol variation display based on the next lottery result stored in the holding storage means. That revive last re variable display (sub CPU 201, the processing of step S366 of FIG. 45) a game machine, characterized in that.

  According to (2), when the pseudo-continuous effect display is performed in the variable display of the symbol based on the previous lottery result stored in the hold storage unit using the prefetch result of the information stored in the hold storage unit, the hold storage is performed. In the symbol variation display based on the lottery result stored in the means, the last re-variation display in the pseudo continuous effect display based on the previous lottery result can be restored. Thus, by performing the pseudo-continuous end effect display and the pseudo-continuous effect display, it becomes possible to perform continuous pseudo-continuous effect display, and once the pseudo-continuous end effect display is performed, the player who is disappointed On the other hand, it is possible to provide the joy of reviving the pseudo-ream effect display in a timely manner.

  (3) In (2), when the symbol display control means performs the pseudo-continuous effect display in the variable display of the symbol based on the next lottery result stored in the holding storage means, Control is performed to display a suggestion image that suggests the number of times of re-variable display (an image called “pseudo-continuous double addition” in FIG. 46G) (sub CPU 201, processing in step S367 in FIG. 45). Gaming machine.

  According to (3), the pseudo-continuous effect display is restored, and a suggestion image that suggests the number of re-variable display in the pseudo-continuous effect display based on the next lottery result is displayed. It is possible to make the player feel as if the number of times is added. In this way, it is possible to provide the player with the pleasure of adding the number of pseudo-reams.

[Effect of the invention]
According to the present invention, it is possible to provide a gaming machine capable of maintaining an expectation for a transition from a pseudo-ream to an advantageous gaming state while maintaining the player's interest in the effect display by the pseudo-ream. Become.

[Appendix 5]
[Background technology]
In a conventional pachinko machine, when a game ball that rolls and flows into a starting prize opening provided on the game board is entered, a winning lottery is performed to shift to a game state advantageous to the player, When a plurality of symbols displayed on a display means such as a display device fluctuate and a winning lottery is won, an advantageous gaming state (so-called jackpot gaming state) triggered by a plurality of symbols stopping in a predetermined combination Migrate to
If a game ball enters the start winning opening while a plurality of symbols are changing on the display means, a winning lottery is performed, while the holding state is maintained until the plurality of symbols changing are stopped. Then, after the fluctuating symbols are stopped, the plurality of symbols are newly fluctuated and stopped based on the winning lottery already performed. The maximum number in the hold state is 4.

  On the other hand, in accordance with the lottery result, the display means displays an effect image or the like in accordance with the change or stop of the symbol, thereby enhancing the expectation of shifting to an advantageous gaming state.

  In Patent Document 1, the variation is maintained until the number of changes in the symbol after the end of the special game reaches the number of final variations, and the production determination means has a plurality of productions in which the correspondence relationship between the fluctuation pattern and the production pattern is defined. It describes that an effect pattern to be executed is selected with reference to one of the pattern tables.

[Prior art documents]
[Patent Literature]
[Patent Document 1] JP-A-2015-51323

[Summary of Invention]
[Problems to be solved by the invention]
However, the selected effect pattern does not include elements other than the effect pattern according to the gaming state and the lottery result, and the effect to be executed tends to seem monotonous to the player.

  An object of this invention is to provide the gaming machine which solves the above-mentioned problem.

[Means for solving problems]
In order to achieve the above object, the present invention has the following configuration.

(1) There is a game area (game area 41) where the game ball rolls and flows down, and a start winning opening (first start port 414a, second start port 414b) in which the game ball can enter the game area. A game board (game board 40) provided with
Launching means (launching device 20) for launching a game ball into the game area by the player's operation;
Lottery means (main CPU 101, processes in steps S34 and S43 in FIG. 8) for performing a lottery for shifting to a gaming state advantageous to the player, with the winning at the start winning opening,
A symbol display means (liquid crystal display device 50) for performing variable display and stop display of a plurality of symbols (three identification symbols 52);
In response to the game ball entering the start winning opening, a plurality of symbols are variably displayed, and the plurality of symbols variably displayed according to the lottery result of the lottery means are stopped and displayed in a predetermined combination. Symbol display control means (sub CPU 201, processing in steps S234 and S235 in FIG. 18),
Effect image display means (liquid crystal display device 50) for effect image display;
Effect image display data storage means (image data ROM 211) for storing a plurality of types of effect image display data;
Effect image display control means (sub CPU 201, process of step S224 in FIG. 18) for controlling the effect image display means in accordance with the lottery result by the lottery means;
Firing ball number storage means (work RAM 203 or main RAM 103) for storing the number of game balls fired by the launching means;
Initializing means (sub-CPU 201 (processing in step S1244 in FIG. 48)) or main for initializing the number of game balls stored in the number-of-fired-ball storage means and the number of times of symbol change display stored in the number-of-changes storage means CPU 101), and
The effect image display control means is initialized by the initialization means, and then the number of game balls stored in the number-of-fired-ball storage means, and the number of symbol fluctuation displays stored in the fluctuation number storage means, The effect image display control using any effect image display data among the plurality of effect image display data stored in the effect image display data storage means (sub CPU 201, step S1241 in FIG. 48). A gaming machine characterized by performing processing.

  According to (1), the effect image is not displayed according to the lottery result of the lottery means, but the number of game balls fired after being initialized by the initializing means and the number of times the symbols are changed are displayed. Since the selected effect image display is performed according to the relationship, it becomes possible to provide a player with a new method of selecting the effect image display, and the monotony of the effect image display can be eliminated.

(2) In (1), a main control unit (main control circuit 100) having the firing ball number storage means (main RAM 103) and the fluctuation number storage means (main RAM 103);
A sub-control unit (sub-control circuit 200) having the effect image display control means,
The main control unit transmits the number of game balls stored in the number-of-fired-ball storage unit and the number of changes stored in the number-of-changes storage unit to the sub-control unit.

(3) In (1), the effect image display control means, as the effect image display, suggests effect image display that suggests a relationship between the number of game balls and the number of times of symbol change display (“battle end” in FIG. 53). The character information 802 of the color) is controlled.
According to (3), for example, an effect display suggested to the player is performed, such as changing the color of the line in the ending effect at the end of the big hit game.

[Effect of the invention]
According to the present invention, it is possible to provide a gaming machine that can eliminate the monotonous effect image display.

[Appendix 6]
[Background technology]
In a conventional pachinko machine, when a game ball that rolls and flows into a starting prize opening provided on the game board is entered, a winning lottery is performed to shift to a game state advantageous to the player, When a plurality of symbols displayed on a display means such as a display device fluctuate and a winning lottery is won, an advantageous gaming state (so-called jackpot gaming state) triggered by a plurality of symbols stopping in a predetermined combination Migrate to
On the other hand, in accordance with the lottery result, the display means displays an effect image or the like in accordance with the change or stop of the symbol, thereby enhancing the expectation of shifting to an advantageous gaming state.

  In Patent Document 1, in a gaming machine in which the first symbol and the second symbol are changed simultaneously, one of the first symbol and the second symbol is opened with a special winning opening which is a game state advantageous to the player. If the game is displayed in a fixed state, the other symbol is stopped at the lost symbol before the predetermined variation time or the predetermined variation according to the type of the symbol that is confirmed and displayed. It is described that the time measurement is interrupted. As described above, conventionally, it is used to vary the variation time of any symbol among a plurality of symbols that vary simultaneously according to the gaming state.

[Prior art documents]
[Patent Literature]
[Patent Document 1] JP-A-2015-51323

[Summary of Invention]
[Problems to be solved by the invention]
However, conventionally, the change time of any symbol is simply changed according to the game state, and no new game is used there.

  The present invention provides a gaming machine capable of giving a player interest and expectation to a game by using a new gameability for changing the variation time in a gaming machine that simultaneously varies a plurality of symbols. The purpose is to do.

[Means for solving problems]
In order to achieve the above object, the present invention has the following configuration.

(1) It has a game area (game area 41) where the game ball rolls and flows down, the game ball can enter the game area, and the game ball is moved to the first start area (first start port winning ball sensor) 116a) and a game board (game board 40) provided with a start winning opening (central role 430) that alternately passes through the second starting area (second starting opening winning ball sensor 116b);
Lottery means (main CPU 101, step S34 in FIG. 8) for performing a lottery for shifting to a gaming state advantageous to the player triggered by the passing of the game ball in either the first start area or the second start area S43)
First symbol display means (special symbol display device 421a) that performs a variable display and a stop display of a plurality of first symbols (first special symbols) according to a lottery result triggered by the passing of the game ball in the first start area. )When,
A second symbol display means (special symbol display device 421b) that performs a variable display (second special symbol) and a stop display of a plurality of second symbols in accordance with the lottery result triggered by the passing of the game ball in the second start area. )When,
In response to the game ball entering the start winning opening, control is performed to enable simultaneous display of the first symbol and the second symbol, and the first symbol and the second symbol are stopped. Design variation display control means (main CPU 101) for performing control for display,
The symbol variation display control means makes the variation display time of the first symbol shorter than the variation display time of the second symbol in the normal gaming state which is not advantageous to the player, and the lottery result by the lottery means is a small hit game. A gaming machine characterized by performing control (main CPU 101, processing in step S1120 in FIG. 58) to shorten the variation time of the second symbol over a predetermined period in response to winning of the transition to the state.

  According to (1), when the transition to the small hit gaming state is won, the variation time of the second symbol is increased by making the variation time of the second symbol shorter than usual over a predetermined period. It is possible to increase the chances for a big hit gaming state by giving lots of lottery opportunities to the players. As a result, it is possible to increase a player's expectation for the transition to an advantageous gaming state.

  (2) In (1), the symbol variation display control means performs control to return the variation time of the second symbol to the normal variation time after the predetermined period for shortening the variation time of the second symbol is completed. A featured gaming machine.

  According to (2), the predetermined period in which the variation time of the second symbol is shortened can be a special period that is advantageous to the player. As a result, it is possible to increase a player's expectation for the transition to an advantageous gaming state.

(3) In (1) and (2), effect image display means (liquid crystal display device 50) for effect image display;
Effect image display control means for controlling the effect image display means in accordance with the lottery result by the lottery means (sub CPU 201, steps S224 in FIG. 17, steps S224 and S225 in FIG. 18), Further comprising
The effect image display control means performs a suggestion effect image display control (sub CPU 201, the process of step S1302 in FIG. 59) suggesting that it is the predetermined period.

  According to (3), the player can grasp whether or not the variation time of the second symbol is short.

[Effect of the invention]
According to the present invention, in a gaming machine that fluctuates a plurality of symbols at the same time, it is possible to give the player interest and expectation for the game by using a new gameability for changing the fluctuation time. It becomes possible to provide.

DESCRIPTION OF SYMBOLS 1 Pachinko machine 16 Direction button 20 Launching device 21 Launching handle 40 Game board 41 Game area 50 Liquid crystal display device 51 Display area 52, 52a, 52b Identification symbol 55, 55a, 55b Reservation symbol 56 Pseudo consecutive number information 58, 58, 702 802 Character image 100 Main control circuit 101 Main CPU
102 Main ROM
103 Main RAM
116a First starting port winning ball sensor 116b Second starting port winning ball sensor 200 Sub control circuit 201 Sub CPU
202 Program ROM
203 Work RAM
210 Display control circuit 211 Image data ROM
414a 1st starting port 414b 2nd starting port 415 Ordinary electric actors 419a, 419b, 419c, 419d General winning port 421 Special symbol display device 430 Central actors 501, 501a to 501d, 502 Piece image 600 Pseudo link type setting menu 701 Reliability information 712 Suggested image

Claims (3)

A game board having a game area in which a game ball rolls and flows down, and a start prize opening in which the game ball can enter the game area;
Launching means for launching a game ball to the game area by the player's operation,
Lottery means for performing a lottery for shifting to a gaming state advantageous to the player, with the winning at the start winning opening,
A symbol display means for performing variable display and stop display of a plurality of symbols;
In response to the game ball entering the start winning opening, a plurality of symbols are variably displayed, and the plurality of symbols variably displayed according to the lottery result of the lottery means are stopped and displayed in a predetermined combination. Design display control means;
Effect image display means for effect image display;
Effect image display data storage means for storing a plurality of types of effect image display data;
Effect image display control means for controlling the effect image display means according to the lottery result by the lottery means,
Firing ball number storage means for storing the number of game balls launched by the launching means;
Initializing means for initializing the number of game balls stored in the number-of-fired-ball storage means and the number of symbol variations displayed in the variation count storage means,
The effect image display control means is initialized by the initialization means, and then the number of game balls stored in the number-of-fired-ball storage means, and the number of symbol fluctuation displays stored in the fluctuation number storage means, A game machine that controls effect image display using any one of effect image display data among a plurality of effect image display data stored in the effect image display data storage means. A main control unit having the firing ball number storage unit and the variation number storage unit;
A sub-control unit having the effect image display control means,
2. The game according to claim 1, wherein the main control unit transmits the number of game balls stored in the firing ball number storage unit and the variation number stored in the variation number storage unit to the sub control unit. Machine. 2. The gaming machine according to claim 1, wherein the effect image display control means controls the suggestion effect image display that suggests a relationship between the number of game balls and the number of times of symbol change display as the effect image display. .