JP2017189289A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine capable of implementing diversified variable display modes without excessively increasing a processing load applied to diversification of the variable display modes.SOLUTION: A screen 874 represents a situation of producing success/failure of adhesion of an alternative element 875 to a central symbol 851e. The alternative element 875 represented on the screen 874 is zoomingly displayed so as to hide the whole of the central symbol 851e. Then, a game machine 10 can continue a variable display of the central symbol 851e hid by the zoomingly-displayed alternative element 875. Screens 876 and 878 represent situations of producing success/failure of adhesion of the alternative element 875 to the central symbol 851e. The screen 879 represents a situation where the alternative element is stuck to all symbols of a large symbol group 851. Regardless of stop modes of the respective symbols of the large symbol group 851, the game machine can display a symbol combination mode corresponding to winning by replacing the respective symbols by the alternative element.SELECTED DRAWING: Figure 153

Description

  The present invention relates to a gaming machine.

  There is a gaming machine that uses an almighty design to increase a player's expectation and produce a game effect that enhances the taste.

JP 2005-87378 A

However, realization of various variable display modes sometimes has a problem of a processing burden related to game effects.
In one aspect, an object of the present invention is to provide a gaming machine that can realize a variety of variable display modes without overloading the processing burden associated with the diversification of the variable display modes.

  In order to achieve the above object, a gaming machine as shown below is provided. The gaming machine includes a display device and a control unit that performs variable display control of identification information in the display device. When the identification information is variably displayed including the first identification element, the control means substitutes the first identification element with the second identification element to derive a specific display result.

  According to one aspect, in a gaming machine, various variable display modes can be realized without overloading the processing burden associated with the diversification of the variable display mode.

It is a perspective view which shows an example of the game machine of 1st Embodiment. It is a front view which shows an example of the game board of 1st Embodiment. It is a block diagram which shows an example of the control system of the game machine of 1st Embodiment. It is a block diagram which shows an example of a structure of the presentation control apparatus of 1st Embodiment. It is a figure which shows an example of the package display apparatus of 1st Embodiment. It is FIG. (1) which shows the flowchart of the main process of 1st Embodiment. FIG. 8 is a (second) diagram illustrating a flowchart of main processing according to the first embodiment. It is a figure which shows the flowchart of the checksum calculation process of 1st Embodiment. It is a figure which shows the flowchart of the initial value random number update process of 1st Embodiment. It is a figure which shows the flowchart of the timer interruption process of 1st Embodiment. It is a figure which shows the flowchart of the input process of 1st Embodiment. It is a figure which shows the flowchart of the switch reading process of 1st Embodiment. It is a figure which shows the flowchart of the output process of 1st Embodiment. It is a figure which shows the flowchart of the payout command transmission process of 1st Embodiment. It is a figure which shows the flowchart of the random number update process 1 of 1st Embodiment. It is a figure which shows the flowchart of the random number update process 2 of 1st Embodiment. It is a figure which shows the flowchart of a winning opening switch / state monitoring process of 1st Embodiment. It is a figure which shows the flowchart of the fraud & winning prize monitoring process of 1st Embodiment. It is a figure which shows the flowchart of a winning number counter update process of 1st Embodiment. It is a figure which shows the flowchart of the gaming machine state check process of 1st Embodiment. It is a figure which shows the flowchart of the payout busy signal check process of 1st Embodiment. It is a figure which shows the flowchart of the special figure game process of 1st Embodiment. It is a figure which shows the flowchart of the start port switch monitoring process of 1st Embodiment. It is a figure which shows the flowchart of the hard random number acquisition process of 1st Embodiment. It is a figure which shows the flowchart of the special figure start port switch common process of 1st Embodiment. It is a figure which shows the flowchart of the special figure pending | holding information determination process of 1st Embodiment. It is a figure which shows the flowchart of the big winning opening switch monitoring process of 1st Embodiment. It is a figure which shows the flowchart of the special figure normal process of 1st Embodiment. It is a figure which shows the flowchart of the special figure normal process transfer setting process 1 of 1st Embodiment. It is a figure which shows the flowchart of the special figure 1 fluctuation start process of 1st Embodiment. It is a figure which shows the flowchart of the special figure 2 fluctuation | variation start process of 1st Embodiment. It is a figure which shows the flowchart of the big hit flag 1 setting process of 1st Embodiment. It is a figure which shows the flowchart of the big hit flag 2 setting process of 1st Embodiment. It is a figure which shows the flowchart of the jackpot determination process of 1st Embodiment. It is a figure which shows the flowchart of the small hit determination processing of 1st Embodiment. It is a figure which shows the flowchart of the special figure 1 stop symbol setting process of 1st Embodiment. It is a figure which shows the flowchart of the special figure 2 stop symbol setting process of 1st Embodiment. It is a figure which shows the flowchart of the special figure information setting process of 1st Embodiment. It is a figure which shows the flowchart of the fluctuation pattern setting process of 1st Embodiment. It is a figure which shows the flowchart of the change start information setting process of 1st Embodiment. It is a figure which shows the flowchart of the special figure change process transition setting process (special figure 1) of 1st Embodiment. It is a figure which shows the flowchart of a special figure fluctuation process transfer setting process (special figure 2) of 1st Embodiment. It is a figure which shows the flowchart of the process during special figure change of 1st Embodiment. It is a figure which shows the flowchart of the special figure display process transition setting process of 1st Embodiment. It is FIG. (The 1) which shows the flowchart of the special figure display middle process of 1st Embodiment. It is FIG. (2) which shows the flowchart of the special figure display middle process of 1st Embodiment. It is a figure which shows the flowchart of the high probability variation frequency update process of 1st Embodiment. It is a figure which shows the flowchart of the production mode information check process of 1st Embodiment. It is a figure which shows the flowchart of a fanfare / interval process transfer setting process of 1st Embodiment. It is a figure which shows the flowchart of the process transfer setting process 1 in the small hitting fanfare of 1st Embodiment. It is a figure which shows the flowchart of a fanfare / interval process of 1st Embodiment. It is a figure which shows the flowchart of the process transfer setting process during special winning opening opening of 1st Embodiment. It is a figure which shows the flowchart of the big winning opening open | release process of 1st Embodiment. It is a figure which shows the flowchart of the big winning opening remaining ball process transfer setting process of 1st Embodiment. It is a figure which shows the flowchart of the big winning opening remaining ball process of 1st Embodiment. It is a figure which shows the flowchart of the process transition setting process 2 of the fanfare / interval of 1st Embodiment. It is a figure which shows the flowchart of the big hit end process transfer setting process of 1st Embodiment. It is a figure which shows the flowchart of the jackpot end process of 1st Embodiment. It is a figure which shows the flowchart of the jackpot end setting process 1 of 1st Embodiment. It is a figure which shows the flowchart of the big hit end setting process 2 of 1st Embodiment. It is a figure which shows the flowchart of the special figure normal process transfer setting process 2 of 1st Embodiment. It is a figure which shows the flowchart of the process during a small hitting fanfare of 1st Embodiment. It is a figure which shows the flowchart of a process process setting process for small hits of 1st Embodiment. It is a figure which shows the flowchart of the middle hit process of 1st Embodiment. It is a figure which shows the flowchart of the small hit operation | movement transfer setting process of 1st Embodiment. It is a figure which shows the timing chart of the small hit operation | movement of 1st Embodiment. It is a figure which shows the flowchart of the small hit remaining ball process transfer setting process of 1st Embodiment. It is a figure which shows the flowchart of the small hit remaining ball process of 1st Embodiment. It is a figure which shows the flowchart of the small hit | end process transfer setting process of 1st Embodiment. It is a figure which shows the flowchart of the small hit | end process of 1st Embodiment. It is a figure which shows the flowchart of the special figure normal process transfer setting process 3 of 1st Embodiment. It is a figure which shows the flowchart of the production command setting process of 1st Embodiment. It is a figure which shows the flowchart of the symbol fluctuation | variation control process of 1st Embodiment. It is a figure which shows an example of the blink control timer initial value table of 1st Embodiment. It is a figure which shows the flowchart of the distribution process of 1st Embodiment. It is a figure which shows the flowchart of a 2 byte distribution process of 1st Embodiment. It is a figure which shows the flowchart of the usual game process of 1st Embodiment. It is a figure which shows the flowchart of the gate switch monitoring process of 1st Embodiment. It is a figure which shows the flowchart of the general power prize winning switch monitoring process of 1st Embodiment. It is a figure which shows the flowchart of the usual figure normal process of 1st Embodiment. It is a figure which shows the flowchart of the usual figure normal process transfer setting process 1 of 1st Embodiment. It is a figure which shows the flowchart of the process transfer setting process in the normal fluctuation of 1st Embodiment. It is a figure which shows the flowchart of the process during the usual figure change of 1st Embodiment. It is a figure which shows the flowchart of the process transition setting process in the normal map display of 1st Embodiment. It is a figure which shows the flowchart of the process during normal map display of 1st Embodiment. It is a figure which shows the flowchart of the process transition setting process in the normal process of 1st Embodiment. It is a figure which shows the flowchart of the process during a common figure of 1st Embodiment. It is a figure which shows the flowchart of the general electric operation transfer setting process of 1st Embodiment. It is a figure which shows the general electric operation | movement timing chart of the normal fluctuation winning device of 1st Embodiment. It is a figure which shows the flowchart of the general electric power remaining ball process of 1st Embodiment. It is a figure which shows the flowchart of the end process shift setting process of the common figure of 1st Embodiment. It is a figure which shows the flowchart of the end process per common figure of 1st Embodiment. It is a figure which shows the flowchart of the usual figure normal process transfer setting process 2 of 1st Embodiment. It is a figure which shows the flowchart of the segment LED edit process of 1st Embodiment. It is a figure which shows the flowchart of the magnet fraud monitoring process of 1st Embodiment. It is a figure which shows the flowchart of the board radio wave fraud monitoring process of 1st Embodiment. It is FIG. (1) which shows the flowchart of the external information edit process of 1st Embodiment. FIG. 6 is a second diagram illustrating a flowchart of external information editing processing according to the first embodiment; It is a figure which shows the flowchart of the main prize ball signal edit process of 1st Embodiment. It is a figure which shows the transmission timing chart of the main prize ball signal of 1st Embodiment. It is a figure which shows the flowchart of the start port signal edit process of 1st Embodiment. It is a figure which shows an example of the during-change display of the special figure 1 in the state 1 of 1st Embodiment. It is a figure which shows an example of the display during the fluctuation | variation of the common figure in the state 1 of 1st Embodiment. It is a figure which shows the comparative example of the display during the fluctuation | variation of the special figure 1 in the state 1 of 1st Embodiment, and the display during the fluctuation | variation of a normal figure. It is a figure which shows an example of the during-change display of the special figure 1 in the state 2 of 1st Embodiment. It is a figure which shows an example of the display during the fluctuation of the usual figure in the state 2 of 1st Embodiment. It is a figure which shows the comparative example of the display during a fluctuation | variation (modified example) of the special figure 1 of 1st Embodiment, and the display during a fluctuation | variation of a usual figure (modified example). It is a figure which shows an example of the screen during a variable display in the display apparatus of 2nd Embodiment. It is a figure which shows an example of the symbol arrangement | sequence of the small symbol group of 2nd Embodiment. It is a figure which shows an example of the symbol arrangement | sequence of the large symbol group of 2nd Embodiment. It is a figure which shows an example of the production flow of 2nd Embodiment. It is a figure which shows an example (the 1) of the screen which the display apparatus of 2nd Embodiment displays. It is a figure which shows an example (the 2) of the screen which the display apparatus of 2nd Embodiment displays. It is a figure which shows an example (the 3) of the screen which the display apparatus of 2nd Embodiment displays. It is a figure which shows an example (the 4) of the screen which the display apparatus of 2nd Embodiment displays. It is a figure which shows an example (the 5) of the screen which the display apparatus of 2nd Embodiment displays. It is a figure which shows an example of the timing chart which shows the symbol replacement timing in the fluctuation | variation display of the small symbol group of 2nd Embodiment. It is a figure which shows an example of the timing chart which shows the temporary stop timing in the fluctuation | variation display of the large symbol group of 2nd Embodiment. It is a figure which shows an example of the 1st replacement symbol of the small symbol group of 2nd Embodiment. It is a figure which shows an example of the 2nd replacement symbol of the small symbol group of 2nd Embodiment. It is a figure which shows an example of the symbol arrangement | sequence of the small symbol group of the modification of 2nd Embodiment. It is a figure which shows an example of the display mode of the large symbol group of 2nd Embodiment. It is a figure which shows an example of the switching of the display mode of the large symbol group according to the state of 2nd Embodiment. It is a figure which shows an example of the switching of the exclusive symbol group of the large symbol group according to the state of 2nd Embodiment. It is a figure which shows an example (the 1) of the screen during a variable display in the display apparatus of the modification of 2nd Embodiment. It is a figure which shows an example (the 2) of the screen during a variable display in the display apparatus of the modification of 2nd Embodiment. It is a figure which shows an example (the 1) of the change display mode of the small symbol group of the modification of 2nd Embodiment. It is a figure which shows an example (the 2) of the change display mode of the small symbol group of the modification of 2nd Embodiment. It is a figure which shows an example (the 3) of the fluctuation | variation display mode of the small symbol group of the modification of 2nd Embodiment. It is a figure which shows an example (the 4) of the change display mode of the small symbol group of the modification of 2nd Embodiment. It is a figure which shows an example (the 5) of the change display mode of the small symbol group of the modification of 2nd Embodiment. It is a figure which shows an example of the symbol arrangement | sequence of the large symbol group of 3rd Embodiment. It is a figure which shows an example of the production flow of 3rd Embodiment. It is a figure which shows an example (the 1) of the screen which the display apparatus of 3rd Embodiment displays. It is a figure which shows an example (the 2) of the screen which the display apparatus of 3rd Embodiment displays. It is a figure which shows an example (the 3) of the screen which the display apparatus of 3rd Embodiment displays. It is a figure which shows an example (the 4) of the screen which the display apparatus of 3rd Embodiment displays. It is a figure which shows an example (the 5) of the screen which the display apparatus of 3rd Embodiment displays. It is a figure which shows the modification (the 1) of the symbol group display of 3rd Embodiment. It is a figure which shows the modification (the 2) of the symbol group display of 3rd Embodiment. It is a timing chart which shows an example of the switching timing of the movie symbol of a 3rd embodiment, and a non-movie symbol. It is a timing chart which shows the modification (the 1) of the switching timing of the movie symbol of a 3rd embodiment, and a non-movie symbol. It is a timing chart which shows the modification (the 2) of the switching timing of the movie symbol of a 3rd embodiment, and a non-movie symbol. It is a figure which shows an example of the outline | summary of the display apparatus of 4th Embodiment, and an accessory. It is a figure which shows an example of the positional relationship of the display surface of a display apparatus of 4th Embodiment, and an accessory. It is FIG. (1) which shows an example of the positional relationship of the production | presentation display element of a 4th Embodiment, and an accessory. It is FIG. (2) which shows an example of the positional relationship of the production | presentation display element of 4th Embodiment, and an accessory. It is a figure which shows an example of the positional relationship of the display surface and movable accessory of the display apparatus of the modification of 4th Embodiment. It is a figure which shows an example of the symbol arrangement | sequence of the large symbol group of 5th Embodiment. It is a figure which shows an example of the production | presentation flow of 5th Embodiment. It is a figure which shows an example (the 1) of the screen which the display apparatus of 5th Embodiment displays. It is a figure which shows an example (the 2) of the screen which the display apparatus of 5th Embodiment displays. It is a figure which shows an example (the 3) of the screen which the display apparatus of 5th Embodiment displays. It is a figure which shows an example (the 4) of the screen which the display apparatus of 5th Embodiment displays. It is a figure which shows the modification of the screen which the display apparatus of 5th Embodiment displays. It is a figure which shows an example of the symbol arrangement | sequence of the large symbol group of 6th Embodiment. It is a figure which shows an example of the display of the large symbol group in the display apparatus of 6th Embodiment. It is a figure which shows an example of the production flow of 6th Embodiment. It is a figure which shows an example (the 1) of the screen which the display apparatus of 6th Embodiment displays. It is a figure which shows an example (the 2) of the screen which the display apparatus of 6th Embodiment displays.

Hereinafter, embodiments will be described in detail with reference to the drawings.
[First Embodiment]
First, a first embodiment will be described with reference to the drawings. FIG. 1 is a perspective view showing an example of the gaming machine according to the first embodiment.

  The gaming machine (pachinko machine) 10 according to the first embodiment includes a front frame 12, and the front frame 12 is assembled to an outer frame (support frame) 11 so as to be capable of opening and closing. The game board 30 (see FIG. 2) is stored in a storage portion (not shown) formed on the front side of the front frame 12. A glass frame (transparent plate (transparent member) holding frame) 15 provided with a cover glass (transparent member) 14 that covers the front surface of the game board 30 is attached to the front frame (main body frame) 12.

  In addition, on the left and right sides of the glass frame 15, lamps and LEDs (Light Emitting Diodes) are built in, and decorations and effects, and notifications when abnormalities occur (for example, if a payout abnormality occurs, the lamps and LEDs are abnormal) A frame decoration device 18 that emits light for lighting (flashing) in a notification color (for example, red) and a speaker (upper speaker) 19a that emits sound (for example, a sound effect) are provided. Further, a speaker (lower speaker) 19b is also provided below the front frame 12. Further, when an abnormality occurs, the abnormality content is notified by sound from the speakers 19a, 19b. Note that a discharge abnormality notification lamp may be provided at a predetermined portion of the glass frame 15.

  Further, at the lower part of the front frame 12, game balls paid out from a payout unit provided on the back side of the game machine 10 and an upper plate (storage plate) 21 for supplying game balls to a not-shown hitting ball launcher are shown. There are provided an upper tray ball outlet 22 that flows out, a lower tray (receiving tray) 23 that stores game balls that are paid out in a state where the upper tray 21 is full, an operation unit 24 of the ball striking device, and the like. Furthermore, an option setting unit 25 for allowing the player to set various options is provided on the upper edge of the upper plate 21. A plurality of selection button switches 25 a are provided around the upper surface of the option setting unit 25, and a determination button switch 25 b is provided at the center of the upper surface of the option setting unit 25. The option setting unit 25 functions as an effect setting unit in which the player sets an effect mode. In this case, the selection button switch 25a functions as an effect button switch for selecting an effect mode, and the determination button switch 25b functions as a determination button switch for determining an effect mode. Further, a key hole 26 for inserting a key for opening or locking the front frame 12 or the glass frame 15 is provided on the lower right side of the front frame 12.

  When the selection button switch 25a functions as an effect button switch, the gaming machine 10 produces an effect in which the player's operation is intervened based on the player's operation received from the selection button switch 25a and the determination button switch 25b. Can be done. For example, an effect in which a player's operation is intervened is an effect in a variable display game (decoration special figure variable display game) on a display device (variable display device) 41 (see FIG. 2). The character displayed on 41 can be operated, or the identification information in the decorative special figure variation display game displayed on the display device 41 can be stopped.

  Further, on the right side of the option setting unit 25, a ball lending button 27 that is operated when a player receives a ball lending from an adjacent ball lending machine, and an operation for discharging a prepaid card from the card unit of the ball lending machine. A discharge button 28, a balance display unit (not shown) for displaying the balance of the prepaid card, and the like are provided. In the gaming machine 10 according to the first embodiment, when the player rotates the operation unit 24, the game ball 32 supplied from the upper plate 21 by the ball striking device is used as a game area 32 on the front surface of the game board 30. Launch towards (see Figure 2). Further, when the player operates the selection button switch 25a and the determination button switch 25b, for example, the volume emitted from the speakers 19a and 19b can be set, or the brightness of the game board 30 can be set. .

Next, the game board 30 will be described with reference to FIG. FIG. 2 is a front view showing an example of the game board according to the first embodiment.
On the surface of the game board 30, a substantially circular game area 32 surrounded by the guide rail 31 is formed. The game area 32 is surrounded by resin side cases 33 and guide rails 31 provided at the four corners of the game board 30. In the game area 32, a center case (game production component) 40 having a display device (variable display device) 41 is arranged at substantially the center. The display device 41 is attached to a recessed portion provided in the center case 40 at a position deeper than the front surface of the center case 40. That is, the center case 40 surrounds the periphery of the display area of the display device 41, protrudes forward from the display surface of the display device 41, and is formed so that the game ball does not easily jump from the surrounding game area 32.

  The display device 41 includes, for example, a device having a display screen such as an LCD (Liquid Crystal Display), a CRT (Cathode Ray Tube). In an area (display area) where an image of the display screen can be displayed, information relating to a game such as a plurality of identification information (special symbols), a character that produces a special figure variation display game, and a background image that enhances the presentation effect is displayed. . On the display screen of the display device 41, a plurality of special symbols assigned as identification information are variably displayed (variably displayed), and a decorative special figure variation display game corresponding to the special diagram variation display game is played. In addition, on the display screen, an image for an effect based on the progress of the game (for example, a jackpot display image, a fanfare display image, an ending display image, etc.) is displayed.

  In addition, the left and right portions of the center case 40 are provided with a board effect device 44 that produces an effect of a game by operating. The board effect device 44 is operable from the state shown in FIG. 2 toward the center of the display device 41.

  On the lower right side of the center case 40 in the game area 32, a normal symbol start gate (common figure start gate) 34 for providing a start condition for the normal figure change display game is provided. A game ball won in the usual start gate 34 is detected by the gate switch 34a (see FIG. 3).

  In the game area 32, three general winning openings 35 are arranged on the lower left side of the center case 40, and one general winning prize is on the lower right side of the center case 40 and below the normal start gate 34. A mouth 35 is arranged. The game balls that have won the general prize opening 35 are detected by a prize opening switch 35a (see FIG. 3).

  In addition, below the center case 40 in the game area 32, a start winning opening 36 (first start winning opening, start winning area) for providing a start condition for the special figure variation display game is provided. The game ball won in the start winning opening 36 is detected by the start opening 1 switch 36a (see FIG. 3).

Also, an ordinary variation winning device 37 (second starting winning opening, starting winning area) for providing a start condition for the special figure variation display game is provided immediately below the starting winning opening 36.
The normal variation winning device 37 includes a movable member 37b that can be converted into a state in which a game ball can easily flow in by opening in a direction in which the upper end side is tilted to the near side. A closed state (a disadvantageous state for the player) in which a game ball cannot flow is maintained. When the result of the normal variation display game becomes a predetermined stop display mode, a game ball is likely to flow into the normal variation winning device 37 by a general electric solenoid 37c (see FIG. 3) as a drive device. It can be changed to a state (a state advantageous to the player). A game ball won in the normal variation winning device 37 is detected by the start port 2 switch 37a (see FIG. 3).

Further, an out-out port 30 a for collecting game balls that have not won a prize-winning port or the like is provided below the normal variation winning device 37.
Further, in the game area 32, below the center case 40 and on the right side of the start winning opening 36, a special variation that can be converted into a state in which a game ball is not accepted and a state in which it is easily accepted depending on the result of the special figure variation display game. A winning device (large winning opening) 38 is provided.

  The special variation winning device 38 has an attacker-type open / close door 38c that can be opened by rotating in a direction in which the upper end side is tilted toward the near side, depending on the result of the special figure variation display game as an auxiliary game. It changes from the closed state (a disadvantageous state for the player) in which the big prize opening is closed to the open state (a state advantageous to the player). That is, the special variable winning device 38 includes a large winning opening that is opened and closed by an open / close door 38c driven by a large winning port solenoid 38b (see FIG. 3) as a driving device, for example, in a special gaming state or in a small hit game. During the state, it is possible to facilitate the inflow of game balls into the big prize opening by converting the big prize opening from the closed state to the open state, and to give a predetermined game value (prize ball) to the player It has become. The game balls that have won the special variable winning device 38 are detected by the big winning opening switch 38a (see FIG. 3).

  In the gaming machine 10 of the first embodiment, among the gaming areas 32 where the game balls flow down, the left area of the center case 40 is the left gaming area, and the right area of the center case 40 is the right gaming area. It is said that. Then, the player can aim for winning at the start winning opening 36 by adjusting the firing force and firing the game ball to the left game area (so-called left-handed), and launch the game ball to the right game area (so-called By right-handing), it is possible to aim to win the normal start gate 34, the normal variation winning device 37, and the special variable winning device 38.

  Here, in the gaming machine 10 of the first embodiment, the flow path forming member 42 attached to the right end portion of the center case 40 is disposed at a position corresponding to the right game area, and the right game area is reached. The game balls thus fired are configured to pass through a flow path formed by the flow path forming member 42. The material of at least the front surface of the flow path forming member 42 is a material that allows a game ball passing through the flow path formed by the flow path forming member 42 to be visually recognized from the outside. A game ball passing through the flow path formed by the forming member 42 (that is, a game ball flowing down the right game area) can be viewed through the flow path forming member 42 from the front of the flow path forming member 42. .

  In addition, on the outside of the game area 32 (here, in the lower right part of the game board 30), the first special figure fluctuation display game and the second special figure fluctuation display game that form the special figure fluctuation display game and the normal figure start gate 34 are displayed. There is provided a collective display device 50 for displaying a game of variable display with a win as a trigger and displaying various information.

  The collective display device 50 includes a round display unit 51 composed of LEDs, a special figure 1 hold display part 52, a special figure 1 symbol display part 53, a special figure 2 symbol display part 54, and a universal symbol display part. 55, an ordinary map hold display unit 56, and a state display unit 57.

Next, a game machine control system will be described with reference to FIG. FIG. 3 is a block diagram illustrating an example of a control system for the gaming machine according to the first embodiment.
The gaming machine 10 includes a game control device 100. The game control device 100 is a main control device (main board) that controls the game in an integrated manner, and is a gaming microcomputer (hereinafter referred to as a gaming microcomputer) 111. A CPU (Central Processing Unit) unit 110 having an input port, an input unit 120 having an input port, an output unit 130 having an output port, a driver, and the like, and the CPU unit 110, the input unit 120, and the output unit 130 are connected. It consists of a data bus 140 and the like.

  The CPU unit 110 includes a game microcomputer 111 called an amusement chip (IC (Integrated Circuit)) and an oscillator such as a crystal resonator. And an oscillation circuit (crystal oscillator) 113 for generating a clock. A DC voltage of a predetermined level such as DC (Direct Current) 32V, DC12V, DC5V generated by the power supply device 400 is supplied to the game control device 100 and electronic components such as a solenoid and a motor driven by the game control device 100 To be enabled.

  The power supply apparatus 400 is an AC (Alternating Current) -DC converter that generates the DC 32V DC voltage from a 24V AC power source, a DC-DC converter that generates a lower level DC voltage such as DC 12V, DC 5V, etc. from the DC 32V voltage. A normal power supply unit 410 having power, a backup power supply unit 420 for supplying a power supply voltage to a RAM (Random Access Memory) in the gaming microcomputer 111 in the event of a power failure, and a power failure monitoring circuit. A control signal generation unit 430 that generates and outputs a control signal such as a power failure monitoring signal and a reset signal for informing the occurrence and recovery of the error.

  In the first embodiment, the power supply device 400 is configured separately from the game control device 100, but the backup power supply unit 420 and the control signal generation unit 430 are integrated on a separate board or the game control device 100, that is, Alternatively, it may be provided on the main substrate. Since the game board 30 and the game control device 100 are to be exchanged when the model is changed, the backup power supply unit 420 and the control signal are provided on a board different from the power supply apparatus 400 or the main board as in the first embodiment. By providing the generation unit 430, it is possible to reduce the cost by removing the generation unit 430.

  The backup power supply unit 420 can be configured with one large-capacity capacitor such as an electrolytic capacitor. The backup power is supplied to the game microcomputer 111 (particularly, the built-in RAM) of the game control apparatus 100, and the data stored in the RAM is held even during a power failure or after the power is shut off. The control signal generation unit 430 monitors the voltage of 32V generated by the normal power supply unit 410, for example, detects the occurrence of a power failure when it drops to, for example, 17V or less, changes the power failure monitoring signal, and resets the signal after a predetermined time. Is output. In addition, a reset signal is output after a predetermined time has elapsed from the time when the power is turned on or the power is restored.

  Further, the game control device 100 is provided with a RAM initialization switch 112. When this RAM initialization switch 112 is operated, an initialization switch signal is generated, and information stored in the RAM 111C in the gaming microcomputer 111 and the RAM in the payout control device 200 is forcibly initialized based on this signal. Processing is performed. Although not particularly limited, the initialization switch signal is read when the power is turned on, and the power failure monitoring signal is repeatedly read in the main loop of the main program executed by the gaming microcomputer 111. The reset signal is a kind of forced interrupt signal and resets the entire control system.

  The gaming microcomputer 111 includes a CPU (central processing unit: microprocessor) 111A, a read-only ROM (Read Only Memory) 111B, and a RAM 111C that can be read and written as needed.

  The ROM 111B stores invariant information (programs, fixed data, various random number judgment values, etc.) for game control in a nonvolatile manner, and the RAM 111C stores a work area for the CPU 111A and various signals and random number values during game control. Used as As the ROM 111B or the RAM 111C, an electrically rewritable nonvolatile memory such as an EEPROM (Electrically Erasable Programmable Read-Only Memory) may be used.

  In addition, the ROM 111B stores a variation pattern table for determining a variation pattern (variation mode) that defines, for example, the execution time of the special figure variation display game, the contents of the effects, the presence or absence of the reach state, and the like. The variation pattern table is a table for the CPU 111A to determine the variation pattern by referring to the variation pattern random numbers 1 to 3 stored as the start memory. The variation pattern table includes a loss variation pattern table selected when the result is lost, a jackpot variation pattern table selected when the result is a big hit, and the like. Furthermore, these pattern tables include a table for determining the second half fluctuation pattern that is the fluctuation pattern after reaching the reach state (such as the second half fluctuation group table and the second half fluctuation pattern selection table), and the fluctuation before reaching the reach state. A table for determining a first-half variation pattern as a pattern (first-half variation group table, first-half variation pattern selection table, etc.) is included.

  Here, the reach (reach state) has a display device whose display state can be changed, the display device derives and displays a plurality of display results at different times, and the plurality of display results are determined in advance. In the gaming machine 10 in which the gaming state becomes a gaming state advantageous to the player (special gaming state) when the special result mode is reached, a part of the plurality of display results has not yet been derived and displayed. A display state in which the display result that is derived and displayed satisfies the condition for the special result mode. In other words, the reach state is deviated from the display condition that is the special result mode even when the display device's variable display control progresses and reaches the stage before the display result is derived and displayed. There is no display mode. And, for example, a state where so-called full rotation reach is performed in a variable display region while maintaining a state where the special result modes are aligned is also included in the reach state. The reach state is a display state at the time when the display control of the display device has progressed to reach a stage before the display result is derived and displayed, and is determined before the display result is derived and displayed. The display state in the case where at least a part of the display results of the plurality of variable display areas satisfies the condition for the special result mode.

  Thus, for example, a decorative special figure fluctuation display game displayed on a display device corresponding to a special figure fluctuation display game fluctuates a plurality of identification information for a predetermined time in each of the left, middle, and right fluctuation display areas on the display device. After displaying, if the change mode is stopped and displayed in the order of left, right, and in order to display the result mode, the left and right change display areas satisfy the conditions for the special result mode (for example, The state in which the variable display is stopped with the same identification information) is the reach state. In addition to this, when the variable display in all the variable display areas is temporarily stopped, the condition that the special result mode is satisfied in any two variable display areas among the left, middle, and right (for example, the same The state that is the identification information (except for the special result mode) may be the reach state, and the remaining one variable display area may be variably displayed from the reach state.

  This reach state includes a plurality of reach effects, and the possibility of deriving a special result mode is different (expectation value is different). As a reach effect, normal reach (N reach), special 1 reach (SP1 reach), Special 2 reach (SP2 reach), Special 3 reach (SP3 reach), and Premier reach are set. The expected value increases in the order of “no reach” <“normal reach” <“special 1 reach” <“special 2 reach” <“special 3 reach” <“premier reach”. In addition, this reach state is included in a variable display mode at least in a case where a special result mode is derived in a special figure variable display game (when a big hit is achieved). That is, it may be included in the variable display mode in the case where it is determined that the special result mode is not derived in the special figure variable display game (when it is out of date). Therefore, the state in which the reach state has occurred is a state that is more likely to be a big hit than the case in which the reach state does not occur.

  The CPU 111A executes a game control program in the ROM 111B, generates control signals (commands) for the payout control device 200 and the effect control device 300, and generates and outputs drive signals for the solenoid and the display device to output the gaming machine 10. Perform overall control. Although not shown, the gaming microcomputer 111 is a jackpot random number for determining the hit of the special figure variation display game, a big hit symbol random number for determining the big hit symbol, a variation pattern in the special figure fluctuation display game (various patterns Random number generation circuit for generating fluctuation pattern random numbers for determining the fluctuation pattern game execution time in the variable display with reach and non-reach display, hit random numbers for determining the hit of the usual variable display game, etc. And a clock generator that generates a clock that gives a timer interrupt signal of a predetermined period (for example, 4 milliseconds (ms)) to the CPU 111A and an update timing of the random number generation circuit based on an oscillation signal (original clock signal) from the oscillation circuit 113. I have.

  In addition, the CPU 111A acquires any one variation pattern table from among a plurality of variation pattern tables stored in the ROM 111B in the process related to the special figure variation display game. Specifically, the CPU 111A determines the game result (winning (big hit or small hit) or off) or the probability state (normal probability state or high probability) of the special figure changing display game as the current gaming state. State), the operation state (short-time operation state) of the normal variation winning device 37 as the current gaming state, the starting memory number, etc., and selects one variation pattern table from among a plurality of variation pattern tables. Get. Here, when executing the special figure fluctuation display game, the CPU 111A serves as fluctuation distribution information acquisition means for acquiring any one of the plurality of fluctuation pattern tables stored in the ROM 111B.

  The payout control device 200 includes a CPU, a ROM, a RAM, an input interface, an output interface, and the like, and drives a payout motor of the payout unit in accordance with a prize ball payout command (command or data) from the game control device 100 to thereby win a prize ball. Control to pay out. Also, the payout control device 200 controls the payout unit to drive out a payout motor based on a loan request signal from the card unit so as to pay out a rental ball.

  The input unit 120 of the gaming microcomputer 111 includes a panel radio wave sensor 62 that detects the emission of radio waves to the gaming machine 10, a starting port 1 switch 36 a in the starting winning port 36, and a starting port 2 switch 37 a in the normal variation winning device 37. These are connected to the gate switch 34a in the usual start gate 34, the prize opening switch 35a, and the big prize opening switch 38a of the special variable prize winning device 38, such that the high level supplied from these switches is 11V and the low level is 7V. An interface chip (proximity I / F) 121 that receives a negative logic signal and converts it into a 0V-5V positive logic signal is provided. The proximity I / F 121 has an input range of 7V-11V, so that the lead wire of the sensor or proximity switch is improperly shorted, the sensor or switch is disconnected from the connector, or the lead wire is disconnected to float. It is possible to detect an abnormal state such as, and output an abnormality detection signal.

  The output of the proximity I / F 121 is supplied to the second input port 123 or the third input port 124 and is read into the gaming microcomputer 111 via the data bus 140. Of the outputs of the proximity I / F 121, when the detection signal of the start port 1 switch 36a, the start port 2 switch 37a, the gate switch 34a, the winning port switch 35a, the big winning port switch 38a, or the abnormality of the sensor or the switch is detected. The abnormality detection signal 1 output to the first input port 123 is input to the second input port 123. Of the outputs of the proximity I / F 121, the detection signal of the panel radio wave sensor 62 and the abnormality detection signal 2 output when an abnormality of the sensor or the switch is detected are input to the third input port 124. Further, the third input port 124 has a detection signal from the fraud detection magnetic sensor 61 provided on the front frame 12 of the gaming machine 10 or a glass frame open detection provided on the glass frame 15 of the gaming machine 10. The detection signal of the switch 63 and the detection signal of the main body frame opening detection switch 64 provided on the front frame (main body frame) 12 of the gaming machine 10 are also input. Note that a vibration sensor switch that detects vibration may be provided in the gaming machine, and the detection signal may be input to the third input port 124.

  Of the outputs of the proximity I / F 121, the output to the second input port 123 is also supplied from the game control device 100 to a test firing test device (not shown) via the relay board 70. Further, of the outputs of the proximity I / F 121, the detection signals of the start port 1 switch 36 a and the start port 2 switch 37 a are input to the gaming microcomputer 111 in addition to the second input port 123.

  As described above, the proximity I / F 121 has a signal level conversion function. In order to enable such a level conversion function, the proximity I / F 121 is supplied with a voltage of 12 V from the power supply device 400 in addition to a voltage of, for example, 5 V required for normal IC operation. It has become.

  The data held by the second input port 123 is asserted (changed to an effective level) by enabling the signal CE (Chip Enable) 2 by the gaming microcomputer 111 decoding the address assigned to the second input port 123. Thus, reading can be performed. The same applies to the third input port 124 and the first input port 122 described later.

  The input unit 120 also includes a fraud radio signal from the payout control device 200 (a signal output when the frame radio wave sensor provided on the front frame 12 detects radio waves), a payout busy signal (payout control device). 200 is a signal indicating whether or not a command can be received), a payout abnormality status signal (status signal indicating a payout abnormality), a shot ball cut switch signal (a signal indicating a lack of game balls before payout), an overflow switch signal (A signal output when it is detected that a predetermined amount or more of game balls are stored in the lower plate 23 (full), a touch switch signal (input to a touch switch provided on the operation unit 24) A first input port 122 is provided which takes in a signal based on it and supplies it to the gaming microcomputer 111 via the data bus 140.

  In addition, the game control device 100 is provided with a Schmitt buffer 125 for inputting signals such as a power failure monitoring signal and a reset signal from the power supply device 400 to the gaming microcomputer 111 and the like. It has a function of removing noise from the signal. The power failure monitoring signal from the power supply device 400 and the initialization switch signal from the RAM initialization switch 112 are temporarily input to the first input port 122 and taken into the gaming microcomputer 111 via the data bus 140. That is, it is treated as a signal equivalent to the signal from the various switches described above. This is because the number of terminals receiving external signals provided in the gaming microcomputer 111 is limited.

  On the other hand, the reset signal RESET from which noise has been removed by the Schmitt buffer 125 is directly input to a reset terminal provided in the gaming microcomputer 111 and also supplied to each port of the output unit 130. Further, the reset signal RESET is output directly to the relay board 70 without passing through the output unit 130, thereby turning off the test test signal held in the port (not shown) of the relay board 70 for output to the test board. Is configured to do. Further, the reset signal RESET may be configured to be output to the test firing test apparatus via the relay board 70. Note that the reset signal RESET is not supplied to the first to third input ports 122, 123, and 124 of the input unit 120. Data set in each port of the output unit 130 by the gaming microcomputer 111 immediately before the reset signal RESET is input needs to be reset to prevent malfunction of the system, but immediately before the reset signal RESET is input, This is because the data read by the gaming microcomputer 111 from each port is discarded when the gaming microcomputer 111 is reset.

  The output unit 130 is provided with a Schmitt buffer 132 disposed on a communication path from the gaming microcomputer 111 to the effect control apparatus 300 and a communication path from the gaming microcomputer 111 to the payout control apparatus 200. Data is transmitted from the game control device 100 to the effect control device 300 and the payout control device 200 by serial communication. The one-way communication is such that no signal can be input to the game control device 100 from the side of the effect control device 300.

  Further, the output unit 130 receives data indicating special symbol information of the variable display game to a test firing test apparatus of an accredited organization that is connected to the data bus 140 and a signal indicating the probability status of the jackpot via the relay board 70. The output buffer 133 is configured to be mountable. The buffer 133 is a component that is not mounted on a game control device (main board) of a pachinko gaming machine as an actual machine (a mass-produced product) installed in the game shop. A detection signal output from the proximity I / F 121, such as a start port switch that does not require any processing, is supplied to the test firing test apparatus via the relay board 70 without passing through the buffer 133.

  On the other hand, detection signals that cannot be supplied to the test firing test apparatus as they are, such as the magnetic sensor 61 and the panel radio wave sensor 62, are once taken into the gaming microcomputer 111 and processed into other signals or information. An error signal indicating that control is not possible is supplied from the data bus 140 to the trial test apparatus via the buffer 133 and the relay board 70. The relay board 70 is provided with a port that takes in the signal output from the buffer 133 and supplies it to the test test apparatus, a connector that relays and transmits the signal line of the detection signal of the switch that does not pass through the buffer, and the like. ing. A chip enable signal CE output from the gaming microcomputer 111 is also supplied to a port on the relay board 70, and a signal of a port selected and controlled by the chip enable signal CE is supplied to the test test apparatus. Yes.

  The output unit 130 is connected to the data bus 140 and includes a large winning opening solenoid 38b for opening the open / close door 38c of the special variable winning device 38 and a general electric solenoid 37c for opening the movable member 37b of the normal variable winning device 37. A second output port 134 for outputting opening / closing data is provided. In addition, the output unit 130 includes a third output port 135 for outputting ON / OFF data of the segment line to which the anode terminal of the LED is connected according to the contents displayed on the collective display device 50, and the collective display device 50. A fourth output port 136 is provided for outputting on / off data of the digit line to which the cathode terminal of the LED is connected.

  Further, the output unit 130 is provided with a fifth output port 137 for outputting information related to the gaming machine 10 such as jackpot information to the external information terminal board 71. The external information terminal board 71 is provided with a photo relay, and can be connected to, for example, an external device (such as an information collection terminal or a game hall internal management device (hall computer)) installed in a game store. Can be supplied to an external device. In addition, a launch permission signal is also output from the fifth output port 137 to the payout control device 200 via the Schmitt buffer 132.

  Further, the output unit 130 receives a switching data signal of the special prize opening solenoid 38b and the general electric solenoid 37c output from the second output port 134, and generates and outputs a solenoid driving signal 138a. The second driver 138b for outputting the ON / OFF drive signal of the segment line on the current supply side of the collective display device 50 output from the third output port 135, and the current of the collective display device 50 output from the fourth output port 136 A third driver 138c that outputs an on / off drive signal for the lead-in digit line, and a fourth driver 138d that outputs an external information signal supplied from the fifth output port 137 to an external device such as a management device to the external information terminal board 71 Is provided.

  The first driver 138a is supplied with DC32V from the power supply device 400 as a power supply voltage so that a solenoid operating at 32V can be driven. Also, DC12V is supplied to the second driver 138b that drives the segment lines of the collective display device 50. Since the third driver 138c for driving the digit line is for drawing out the digit line corresponding to the display data with a current, the power supply voltage may be either 12V or 5V.

  The second driver 138b that outputs 12V causes a current to flow to the anode terminal of the LED via the segment line, and the third driver 138c that outputs the ground potential draws the current from the cathode terminal via the digit line. The power supply voltage flows through the LEDs sequentially selected in step 1 so that the LEDs are lit. The fourth driver 138d that outputs the external information signal to the external information terminal board 71 is supplied with DC12V in order to give the external information signal a level of 12V. Note that the buffer 133, the second output port 134, the first driver 138a, and the like may be provided on the output board 130 of the game control apparatus 100, that is, on the relay board 70 side instead of the main board.

  Furthermore, the output unit 130 is provided with a photocoupler 139 for transmitting information such as an identification code and a program of each gaming machine to the external inspection device 500. The photocoupler 139 is configured to be capable of two-way communication so that the gaming microcomputer 111 can transmit and receive data to and from the inspection device 500 through serial communication. Such data transmission / reception is performed using the serial communication terminal of the gaming microcomputer 111 as in the case of a general-purpose microprocessor. Not provided.

Next, the configuration of the effect control device 300 will be described with reference to FIG. FIG. 4 is a block diagram illustrating an example of the configuration of the effect control device of the first embodiment.
The effect control device 300 displays a video on the display device 41 in accordance with commands and data from the main control microcomputer 311 and the main control microcomputer 311, similarly to the game microcomputer 111. A VDP (Video Display Processor) 312 as a graphic processor for performing image processing for this purpose, and a sound source LSI 314 for controlling the output of sound for reproducing various melodies and sound effects from the speakers 19a and 19b.

  The main control microcomputer 311 has a PROM 321 composed of a PROM (programmable read only memory) that stores programs executed by the CPU and various data, a RAM 322 that provides a work area, and can retain stored contents even when power is not supplied during a power failure. An FeRAM (Ferroelectric RAM) 323 and an RTC (real-time clock) 338 serving as a clock means for generating information indicating the current date and time (year, month, day of the week, time, etc.) are connected. A RAM for providing a work area is also provided inside the main control microcomputer 311. A WDT (watchdog timer) circuit 324 is connected to the main control microcomputer 311. The main control microcomputer 311 analyzes the command from the game microcomputer 111, decides the contents of the presentation and instructs the contents of the output video to the VDP 312, instructs the sound source LSI 314 to reproduce the sound, lights the decoration lamp, motors And control of solenoid drive control, production time management, and the like.

  The VDP 312 is provided with a RAM 312a for providing a work area and a scaler 312b for enlarging and reducing images. In addition, the VDP 312 includes an image ROM 325 in which character images and video data are stored, and an ultra-high-speed VRAM (Video RAM) used for expanding and processing image data such as characters read from the image ROM 325. ) 326 is connected.

  Although not particularly limited, the main control microcomputer 311 and the VDP 312 are configured to transmit and receive data in a parallel manner. By transmitting and receiving data in parallel, commands and data can be transmitted in a shorter time than in the case of serial.

  From the VDP 312 to the main control microcomputer 311, a vertical synchronization signal VSYNC for synchronizing the video of the display device 41 and lighting of the decoration lamps provided on the glass frame 15 and the game board 30, and a synchronization signal for giving data transmission timing STS is input. The VDP 312 notifies the main control microcomputer 311 that it is waiting to receive commands and data from the interrupt control signals INT0 to n and the main control microcomputer 311 in order to notify the processing status such as the end of drawing in the VRAM. A wait signal WAIT and the like are also input.

  The effect control device 300 is provided with a signal conversion circuit 313 that generates a video signal to be transmitted to the display device 41 by an LVDS (Low Voltage Differential Signaling) method. Video data, a horizontal synchronization signal HSYNC, and a vertical synchronization signal VSYNC are input from the VDP 312 to the signal conversion circuit 313, and the video generated by the VDP 312 is input to the display device 41 via the signal conversion circuit 313. Is displayed.

  The sound source LSI 314 is connected to an audio ROM 327 that stores audio data. The main control microcomputer 311 and the tone generator LSI 314 are connected via an address bus / data bus 340. An interrupt signal INT is input from the tone generator LSI 314 to the main control microcomputer 311. The effect control device 300 is provided with an amplifier circuit 337 including an audio power amplifier that drives an upper speaker 19 a provided on the glass frame 15 and a lower speaker 19 b provided on the front frame 12, and is generated by the sound source LSI 314. The sound is output from the upper speaker 19a and the lower speaker 19b via the amplifier circuit 337.

  In addition, the effect control device 300 is provided with an interface chip (command I / F) 331 that receives a command transmitted from the game control device 100. An ornamental special figure holding number command, a decorative special figure command, a variation command, a stop information command, etc. transmitted from the game control device 100 to the production control device 300 via this command I / F 331 are produced as a production control command signal (production command ). Since the game microcomputer 111 of the game control device 100 operates at DC 5V and the main control microcomputer 311 of the effect control device 300 operates at DC 3.3V, the command I / F 331 is provided with a signal level conversion function. Yes.

  The effect control device 300 includes a board decoration LED control circuit 332 for driving and controlling a board decoration device 46 having LEDs (light emitting diodes) provided on the game board 30 (including the center case 40), and a glass frame 15. Frame decoration LED control circuit 333 for driving and controlling a frame decoration device (for example, the frame decoration device 18) having LEDs (light emitting diodes) provided, and board effects provided on the game board 30 (including the center case 40) There is provided a board effect movable body control circuit 334 that drives and controls the device 44 (for example, a movable accessory that enhances the effect of the effect in cooperation with the effect display on the display device 41). These control circuits 332 to 334 that drive and control lamps, motors, solenoids, and the like are connected to the main control microcomputer 311 via an address bus / data bus 340. Note that a frame effect device provided with a drive source such as a motor (for example, a motor that operates an effect device) is provided on the glass frame 15, and a frame effect movable body control circuit that drives and controls the frame effect device is provided. Good.

  Further, the effect control device 300 includes an effect agent switch 47 for detecting the selection button switch 25a and the determination button switch 25b of the option setting unit 25 provided on the glass frame 15, the initial position of the motor in the board effect device 44, and the like. The main control microcomputer by detecting the on / off state of the (production motor switch) and inputting a detection signal to the main control microcomputer 311 and the state of the volume control switch 335 provided in the production control device 300 A switch input circuit 336 for inputting a detection signal to 311 is provided.

  The normal power supply unit 410 of the power supply apparatus 400 drives a motor or a solenoid to supply a desired level of DC voltage to the effect control apparatus 300 having the above-described configuration and electronic components controlled thereby. In addition to DC32V, display device 41 consisting of a liquid crystal panel, DC12V for driving motors and LEDs, and DC5V as the power supply voltage for command I / F 331, a voltage of DC15V for driving motors, LEDs, and speakers is generated. Is configured to do. Further, when an LSI operating at a low voltage such as 3.3 V or 1.2 V is used as the main control microcomputer 311, a DC − for generating DC 3.3 V or DC 1.2 V based on DC 5 V is used. A DC converter is provided in the effect control device 300. The DC-DC converter may be provided in the normal power supply unit 410.

  The reset signal generated by the control signal generation unit 430 of the power supply apparatus 400 is supplied to the main control microcomputer 311 to put the device into a reset state. In addition, it is output from the main control microcomputer 311 and supplied to the VDP 312 (VDRESET signal), the tone generator LSI 314 and the amplifier circuit 337 (SNDRESET signal), and control circuits 332 to 334 (IORESET signal) for driving and controlling lamps, motors and the like. These are reset. In addition, a cooling FAN 45 that cools various parts of the gaming machine 10 is connected to the effect control device 300, and the cooling FAN 45 is driven in a state in which the power of the effect control device 300 is turned on.

Next, game control performed in these control circuits will be described.
In the CPU 111A of the game microcomputer 111 of the game control device 100, a random number value for determining the hit of the normal game is extracted based on the input of the detection signal of the game ball from the gate switch 34a provided in the normal game start gate 34, and the ROM 111B. Compared with the determination value stored in the table, the process of determining a missed hit of the normal map display game is performed. Then, after the identification symbol (identification information) is variably displayed for a predetermined time on the regular symbol display unit 55, a process for displaying a regular symbol variation display game to be stopped is performed. When the result of the normal figure fluctuation display game is a win, a special result mode corresponding to each of the first per stop symbol to the third per stop symbol is displayed on the general symbol display unit 55, and the general electric solenoid 37c. Is operated, and the movable member 37b of the normal variation winning device 37 is controlled to be opened as described above for a predetermined time (for example, 0.5 seconds or 1.7 seconds). That is, the game control device 100 serves as conversion control execution means for performing conversion control of the conversion member (movable member 37b). In addition, when the result of the usual figure change display game is out of place, the normal symbol display unit 55 performs control to display the result form of the deviation.

  In addition, a start winning (starting memory) is stored based on the input of a game ball detection signal from the start opening 1 switch 36a provided in the starting winning opening 36, and based on this start storage, the first special figure variation display game is stored. The big hit determination random number value is extracted and compared with the determination value stored in the ROM 111B, and a process of determining a miss of the first special figure variation display game is performed. In addition, the start memory is stored based on the input of the detection signal of the game ball from the start port 2 switch 37a provided in the normal variation winning device 37, and based on this start memory, for the big hit determination of the second special figure variable display game. A random number value is extracted and compared with a determination value stored in the ROM 111B, and a process of determining a miss of the second special figure variation display game is performed.

  Then, the CPU 111 </ b> A of the game control device 100 outputs a control signal (effect control command) including the determination results of the first special figure variation display game and the second special figure variation display game to the effect control device 300. Then, after the identification symbol (identification information) is variably displayed for a predetermined time on the special symbol 1 symbol display unit 53 and the special symbol 2 symbol display unit 54, processing for displaying a special symbol variation display game to be stopped is performed. In other words, the game control device 100 serves as a game control means for performing the progress control of the variable display game based on the winning of the game ball flowing down the game region 32 to the start winning region (start winning port 36, normal variation winning device 37). .

  In addition, in the production control device 300, based on the control signal from the game control device 100, the display device 41 performs a process of displaying the decorative special figure fluctuation display game corresponding to the special figure fluctuation display game. Further, the effect control device 300 performs setting of the effect state, output of sounds from the speakers 19a and 19b, control of light emission of various LEDs, and the like based on the control signal from the game control device 100. That is, the production control device 300 serves as production control means for controlling production related to a game (such as a variable display game).

  Then, when the result of the special figure variation display game is a big hit or a small hit, the CPU 111A of the game control device 100 displays the special result mode or the small hit result mode in the special figure 1 symbol display unit 53 or the special figure 2 symbol display unit 54. And a process for generating a special game state or a small hit game state (that is, a process for executing a special game or a small hit game) is performed. In the process of generating the special game state or the small hit game state, the CPU 111A can open the open / close door 38c of the special variable prize device 38 by the big prize solenoid 38b, for example, so that the game ball can flow into the big prize mouth. To control. Then, until the condition that either a predetermined number (for example, 9) of game balls wins the grand prize winning opening or a predetermined openable time elapses from the opening of the big winning opening is achieved. The control (cycle game) is performed in which the release is set as one round and this is repeated (repeated) a predetermined number of rounds. In other words, the game control device 100 serves as a big prize opening / closing control means for performing control for opening and closing the big prize opening when the stop result mode becomes the special result mode. When the result of the special figure variation display game is out of control, the special figure 1 symbol display unit 53 and the special figure 2 symbol display unit 54 are controlled to display the result of the deviation.

  In addition, the game control device 100 can generate a high probability state as a game state after the special game state ends based on the result mode of the special figure variation display game. This high probability state is a state in which the probability of a hit result in the special figure variation display game is higher than the normal probability state. Moreover, even if it becomes a high probability state based on the result aspect of any of the first special figure fluctuation display game and the second special figure fluctuation display game, the first special figure fluctuation display game and the second special figure Both of the variable display games are in a high probability state.

  In addition, the game control device 100 can generate a time-short state (a specific game state, a normal figure high probability state) as a game state after the special game state ends, based on a result mode of the special figure variation display game. In this short state, the probability that the hit result of the normal map change display game (normal map probability) is higher than the normal probability (normal low probability state) of 0 (normal high probability state). Is possible. As a result, control is performed such that the opening time of the normal variation winning device 37 per unit time is longer than when the normal variation winning device 37 is in the normal low probability state. Here, in the normal variation winning device 37 in this embodiment, the normal probability is set to “0” so as not to open the movable member 37b in the normal gaming state.

  Also, in the short time state, the execution time of the normal map change display game (the normal map change time) is, for example, 500 milliseconds, and the normal map stop time for displaying the result of the normal map change display game is, for example, 600 milliseconds. When the normal variation winning game 37 is released as a result of the normal variation display game being won, the first stop symbol opening time (general power opening time) and the number of releases (for example, 500 msec × 1), Opening time (general power opening time) of the second per stop symbol and the number of times of opening (for example, 1700 msec × 2 times), opening time of the third per stop symbol (opening time of the general power) and the number of times of opening (for example, 1700 ms ×) 3 times).

  In addition, the execution time of the general map variable display game, the normal map stop time, the number of general power releases, and the general power open time are set appropriately so as to control the normal variable prize winning game 37 and the normal variable winning device 37 to be in the short-time operation state. For example, in the short-time state, it is possible to control the execution time of the above-described normal variation display game (ordinary variation time) to be the second variation display time shorter than the first variation display time. (For example, 10,000 milliseconds is 1000 milliseconds). Further, in the short time state, it is possible to control the general map stop time for displaying the result of the normal map change display game so as to be the second stop time shorter than the first stop time (for example, 1604 milliseconds). 704 ms). Also, in the short-time state, when the normal variation winning game 37 is released as a result of the normal-variation display game being won, the opening time (general power open time) is set to the normal state (low-probability state) It is possible to control so that the second opening time is longer than one opening time (for example, 100 milliseconds is 1352 milliseconds). Further, in the short-time state, the number of times of opening of the normal variation winning device 37 (the number of times of normal power release) is larger than the first number of times of opening (for example, 2 times) with respect to the result of one hit of the normal fluctuation display game. It is possible to set the number of times of opening (for example, 4 times) as the second opening number. Also, in the short-time state, the probability that the hit result of the normal-variable display game (normal-probability) is higher than the normal probability (normal low-probability state, for example 1/251) in the normal operation state. Probability (usually high probability state, eg 250/251) is possible.

  In the short time state, the normal variation winning device 37 is in an open state by changing any one or more of the normal time fluctuation time, the normal time stop time, the number of times of normal power release, the normal power release time, and the normal figure probability. Make the conversion time longer than usual. It is also possible to set a plurality of types of time-short states that are different from each other. Moreover, when it is a hit, either the first opening mode or the second opening mode may be selected. In this case, the selection probabilities of the first release mode and the second release mode may be different. Further, the high probability state and the short time state can be generated independently, and both can be generated at the same time, or only one of them can be generated.

  Next, the configuration of the collective display device will be described with reference to FIG. FIG. 5 is a diagram illustrating an example of the collective display device according to the first embodiment. The collective display device 50 includes 32 LEDs from LED_00 to LED_31. The collective display device 50 displays various states according to the lighting modes of the LED_00 to the LED_31.

  The collective display device 50 distributes various state display functions from LED_00 to LED_31, so that the round display unit 51, the special figure 1 hold display part 52, the special figure 1 symbol display part 53, and the special figure 2 symbol display part 54 are displayed. A general symbol display unit 55, a general symbol hold display unit 56, and a state display unit 57. The round display unit 51 displays the number of rounds in the special figure game by lighting the four LEDs from LED_00 to LED_03. The special figure 1 hold display unit 52 displays the number of holds in the special figure 1 game by lighting the two LEDs LED_04 and LED_05. The special figure 1 symbol display unit 53 displays the symbols in the special figure 1 game by lighting the eight LEDs from LED_06 to LED_13. The special figure 2 symbol display unit 54 displays the symbols in the special figure 2 game by lighting the eight LEDs from LED_14 to LED_21. The regular symbol display unit 55 displays symbols in the regular symbol game by lighting the four LEDs LED_24 to LED_27. The usual figure hold display unit 56 displays the number of holds in the usual figure game by lighting the two LEDs LED_28 and LED_29. The state display unit 57 displays the gaming state in the special game according to the lighting mode of the two LEDs LED_30 and LED_31. The special figure 2 hold display unit 58 displays the number of holds in the special figure 2 game by lighting the two LEDs LED_22 and LED_23.

  Hereinafter, control of a gaming machine that performs such a game will be described. First, the control executed by the game microcomputer 111 of the game control device 100 will be described. The control process by the gaming microcomputer 111 mainly includes a main process shown in FIGS. 6 and 7 and a timer interrupt process shown in FIG. 10 performed at a predetermined time period (for example, 4 milliseconds).

[Main processing]
First, the main process will be described. FIG. 6 is a diagram (part 1) illustrating a flowchart of the main process according to the first embodiment, and FIG. 7 is a diagram (part 2) illustrating a flowchart of the main process according to the first embodiment. The main process is a process executed by the CPU 111A.

  The main process is started when the power is turned on. In this main process, as shown in FIGS. 6 and 7, first, the process of prohibiting the interrupt (step S1) is performed, and then the start address of the area in which the value of the register or the like is saved when the interrupt occurs. A stack pointer setting process (step S2) for setting a certain stack pointer is performed. Next, register bank 0 is designated (step S3), and the upper address of the RAM head address is set in a predetermined register (for example, D register) (step S4). In the case of the first embodiment, the address range of the RAM 111C is 0000h to 01FFh, and the upper order is 00h or 01h. In step S4, 00h at the head of the address range of the RAM 111C is set.

  Next, a firing stop signal is output to set the firing permission signal to a prohibited state (step S5). The launch permission signal is set to a prohibited state when at least one of the game control device 100 and the payout control device 200 outputs a launch stop signal, and the launch of the game ball is prohibited.

  Thereafter, the state of the input port 1 (first input port 122) is read (step S6), and a process for setting a power-on delay timer is performed (step S7). In this process, by setting a predetermined initial value, slave control means (for example, the payout control apparatus 200 or the effect control apparatus 300) that performs various controls in accordance with instructions from the game control apparatus 100 serving as the main control means. A waiting time (for example, 3 seconds) for waiting for the program to start normally is set. As a result, when the power is turned on, the game control device 100 is first started up and the command is sent to the slave control device before the slave control device (for example, the payout control device 200 or the production control device 300) is started up. Can avoid missing commands. That is, the game control device 100 delays the start of the main control means (game control device 100) and waits for the start of the slave control devices (the payout control device 200, the effect control device 300, etc.) when the power is turned on. A standby means for setting the standby time is provided.

  In addition, the power-on delay timer is timed using a storage area (a RAM area or a register that is not subject to validity determination) that is not subject to the validity determination (checksum calculation) of the data held in the RAM area. Thereby, when calculating check data such as the checksum of the RAM area, it is not necessary to exclude a part of the RAM area, so that it is possible to prevent the control at power-on from becoming complicated.

  Note that an initialization switch signal is input to the first input port 122. By reading the state of the first input port 122 before the start of the standby time, the operation of the RAM initialization switch 112 can be performed. It can be detected reliably. That is, when the state of the RAM initialization switch 112 is read after the standby time has elapsed, the RAM initialization switch 112 is operated after waiting for the standby time to elapse, or until the standby time elapses after the power is turned on. 112 needs to be operated continuously. However, by reading the status before the start of the standby time, even if such annoying operation is not performed, it can be detected by performing the operation immediately after the power is turned on, and the initialization operation performed when the power is turned on Can be prevented from being accepted.

  Next, a process for setting a power-on delay timer (for example, about 3 seconds) (step S7) is performed, and then a process for monitoring the time of standby time and the occurrence of a power failure during the standby time (steps S8 to S12). To do. First, the number of times (for example, twice) that the power failure monitoring signal input from the power supply device 400 is read and checked via the port and the data bus is set (step S8), and whether or not the power failure monitoring signal is on is determined. A determination is made (step S9).

  When the power failure monitoring signal is on (step S9; Y), it is determined whether or not the power failure monitoring signal is on for the number of checks set in step S8 (step S10). If the power failure monitoring signal is not on for the number of checks (step S10; N), the process returns to the determination (step S9) of whether or not the power failure monitoring signal is on. Further, when the power failure monitoring signal is kept on for the number of checks (step S10; Y), that is, when it is determined that a power failure has occurred, it waits for the power to the gaming machine 10 to be cut off. . In this way, it is possible to prevent a power outage from being erroneously detected due to noise, etc. by determining that a power outage has occurred when the power outage monitoring signal is continuously received for a predetermined period of time, and appropriately deal with malfunctions at power-on. be able to.

  That is, the game control device 100 serves as a power failure monitoring means for monitoring the occurrence of a power failure during a predetermined standby time. As a result, it is possible to cope with a power failure that occurs during the period in which the activation of the game control device 100 that constitutes the main control means is delayed, and it is possible to appropriately deal with a problem at the time of power-on. Note that until the end of the standby time, access to the RAM 111C is not permitted, and the stored contents at the time of the previous power shut-off are retained. There is no need. For this reason, even if a power failure occurs during the standby time, it is not necessary to take a backup of the RAM 111C, and the control burden can be reduced.

  On the other hand, when the power failure monitoring signal is not on (step S9; N), that is, when a power failure has not occurred, the power-on delay timer is updated by “−1” (step S11), and the timer value is “0”. ] Is determined (step S12). If the value of the timer is not 0 (step S12; N), that is, if the standby time has not ended, the process returns to the process of setting the number of checks of the power failure monitoring signal (step S8). When the timer value is “0” (step S12; Y), that is, when the standby time is over, access to a read / write RWM (Read Write Memory) such as the RAM 111C or EEPROM is permitted (step S12). S13), off-data is output to all output ports (set to a state in which there is no output) (step S14).

  Next, a serial port (a port pre-installed in the gaming microcomputer 111, which is used for communication with the effect control device 300 and the payout control device 200 in this first embodiment) is set (step S15). It is determined whether or not the RAM initialization switch 112 is turned on from the state of the first input port 122 read in advance (step S16).

  When the RAM initialization switch 112 is OFF (step S16; N), it is determined whether or not the value of the power failure inspection area 1 in the RWM is normal power interruption inspection area check data 1 (for example, 5Ah) (step S16). If it is normal (step S17; Y), it is determined whether or not the value of the power failure inspection area 2 in the RWM is normal power interruption inspection area check data 2 (for example, A5h) (step S18). If the value of the power failure inspection area 2 is normal (step S18; Y), a checksum calculation process for calculating a checksum of a predetermined area in the RWM is performed (step S19). It is determined whether or not the checksums match (step S20). If the checksums match (step S20; Y), the process proceeds to step S21 (FIG. 7), and processing is performed when normal recovery from a power failure is performed.

  Further, when it is determined that the RAM initialization switch 112 is on (step S16; Y), or when it is determined that the check data in the power failure inspection area is not normal data (step S17; N or step S18; N). If it is determined that the checksum is not normal (step S20; N), the process proceeds to step S26 (FIG. 7) to perform initialization processing. That is, the RAM initialization switch 112 constitutes an initialization operation unit that can be operated from the outside, and the game control device 100 initializes data stored in the RAM 111C based on the operation of the initialization operation unit. To make it possible.

  In step S21 (FIG. 7), the initial value at the time of power failure recovery is saved in the area to be initialized (step S21). The areas to be initialized here are a power failure inspection area, a checksum area, and an area related to error fraud monitoring. The busy signal status area for storing the state of the payout busy signal, which is a signal indicating whether or not the payout control device 200 can accept the command, is also cleared, indicating that the state of the payout busy signal has not been determined. Undefined state. Similarly, the touch switch signal state monitoring area for storing the state of the touch switch signal is also cleared, and an undefined state indicating that the state of the touch switch signal has not been determined. Thereafter, an area for storing the game state in the RWM is examined to determine whether or not the special figure has a high probability (the probability state of the special figure variation display game is a high probability state) (step S22). Here, when the special figure is not in high probability (step S22; N), steps S23 and S24 are skipped and the process proceeds to step S25. On the other hand, when the special figure is in a high probability (step S22; Y), the on-information is saved in the high probability notification flag area (step S23), and for example, a high probability notification LED (error display) provided in the collective display device 50 is saved. Data) is saved in the segment area (step S24). And the command at the time of the power failure restoration corresponding to the process number prepared in order to perform the special figure game process mentioned later reasonably is transmitted to an effect control board (effect control apparatus 300) (step S25), and step S31 Proceed to In the case of the first embodiment, in step S25, a model designation command, a special figure 1 hold number command, a special figure 2 hold number command, a probability information command, a screen designation command (a customer waiting demonstration screen command, Otherwise, send multiple commands such as recovery screen commands). Depending on the model, in addition to these commands, performance number information and high probability number information are transmitted.

  On the other hand, when the process proceeds from step S16, S17, S18, S20 to step S26, the RAM access prohibited area is set to the access permitted (step S26), and all the areas including the busy signal status area and the touch switch signal state monitoring area are set. The RAM area is cleared to zero (step S27), and the RAM access prohibition area is set to access prohibition (step S28). Then, the initial value at the time of RAM initialization is saved in the area to be initialized (step S29). The area to be initialized here is an area relating to the setting of the customer waiting demonstration area and the production mode. And the command at the time of RAM initialization is transmitted to an effect control board (effect control apparatus 300) (step S30), and it transfers to step S31. In the case of the first embodiment, in step S30, a model designation command, a special figure 1 hold number command, a special figure 2 hold number command, a probability information command, a RAM initialization command (a customer waiting demonstration screen is displayed and A plurality of commands such as time (for example, a command for informing the RAM initialization with light and sound) are transmitted. Depending on the model, in addition to these commands, performance number information and high probability number information are transmitted.

  In step S31, processing for starting a CTC circuit that generates a timer interrupt signal and a random number update trigger signal (CTC (Counter / Timer Circuit)) in the gaming microcomputer 111 (clock generator) is performed. The CTC circuit is provided in a clock generator in the gaming microcomputer 111. The clock generator divides the oscillation signal (original clock signal) from the oscillation circuit 113, a timer interrupt signal having a predetermined period (for example, 4 milliseconds) to the CPU 111A based on the divided signal, and And a CTC circuit that generates a signal CTC that gives a trigger for updating a random number supplied to the random number generation circuit.

  After the CTC activation process in step S31, a process for setting the activation of the random number generation circuit is performed (step S32). Specifically, the CPU 111A performs setting of a code (specified value) for starting the random number generation circuit to a predetermined register (CTC update permission register) in the random number generation circuit. A bit transposition pattern of a hard random number (here, a big hit random number) generated by the hardware of the random number generation circuit is also set. Bit transposition pattern is a method of permutation when the extracted random bit arrangement (the arrangement before the upper bit transposition) is replaced in a predetermined order and stored as a different bit arrangement (the arrangement after the lower bit transposition). It is a pattern that defines By replacing the bits of the random numbers according to this bit transposition pattern, the regularity of the random numbers can be broken and the confidentiality of the random numbers can be improved. The bit transposition pattern may be a single fixed pattern or may be selected from a plurality of patterns prepared in advance. Further, the user may arbitrarily set it.

  After that, the value of a predetermined register (soft random number registers 1 to n) in the random number generation circuit at the time of power-on is extracted, and various corresponding initial value random numbers (in the case of the first embodiment, the special symbol hit pattern is determined) RWM as the initial value (start value) of random numbers (big hit design random numbers, small hit design random numbers), random numbers that determine the hit of the normal figure (per random number), random numbers that determine the hit pattern of the normal figure (per hit design random number) Is saved in a predetermined area (step S33), and an interrupt is permitted (step S34). The random number generation circuit in the CPU 111A used in the first embodiment is configured such that the initial value of the soft random number register is changed every time the power is turned on. Therefore, this value is used as an initial value (start value) of various initial value random numbers. ), It is possible to break the regularity of random numbers generated by software, making it difficult for a player to obtain illegal random numbers.

  Subsequently, an initial value random number update process (step S35) is performed to update the values of various initial value random numbers and destroy the regularity of the random numbers. Although not particularly limited, in the first embodiment, the big hit random number, the big hit symbol random number, the small hit symbol random number, the hit random number, and the hit symbol random number are generated using random numbers generated by a random number generation circuit. Configured to generate. However, the big hit random number is a so-called “high-speed counter” that is updated based on a clock having a speed equal to or higher than the operation clock of the CPU. The big hit symbol random number, the small hit symbol random number, the hit random number, This is a “low-speed counter” that is updated based on a CTC output (CTC (CTC2) different from CTC (CTC0) for timer interrupt processing) having the same cycle as the timer interrupt processing that is a processing unit. In addition, in the big hit design random number, the small hit design random number, the hit random number, and the hit design random number, each time the random number makes a round, each initial value random number (generated by software) is used to change the start value. Is adopted. Each random number may be updated by a counter using “+1” or “−1”, or may be updated by a random method in which all values within a range appear without being overlapped until one round is completed. That is, the big hit random number is a random number updated only by hardware, and the big hit symbol random number, the small hit symbol random number, the hit random number, and the hit bonus random number are random numbers updated by hardware and software.

  After the initial value random number update process in step S35, the number of times (for example, twice) of reading and checking the power failure monitoring signal input from the power supply device 400 via the port and the data bus is set (step S36). It is determined whether the signal is on (step S37). If the power failure monitoring signal is not on (step S37; N), the process returns to the initial value random number update process (step S35). That is, when a power failure has not occurred, the initial value random number update processing and the power failure monitoring signal check (loop processing) are repeated. By permitting an interrupt before the initial value random number update process (step S35) (step S34), if a timer interrupt occurs during the initial value random number update process, the interrupt process is executed preferentially. Can be prevented from being interrupted by waiting for the initial value random number update process.

  The initial value random number update process in step S35 includes a method of performing the initial value random number update process in the timer interrupt process in addition to the main process, and when such a method is adopted, In order to avoid executing the initial value random number update process, when performing the initial value random number update process in the main process, it is necessary to disable the interrupt and then update it to release the interrupt. If the initial value random number update process in the timer interrupt process is not performed as in the embodiment and only in the main process, there is no problem even if the interrupt is canceled before the initial value random number update process, This has the advantage that the main process is simplified.

  If the power failure monitoring signal is on (step S37; Y), it is determined whether or not the power failure monitoring signal is on for the number of checks set in step S36 (step S38). If the power failure monitoring signal is not on for the number of checks (step S38; N), the process returns to the determination (step S37) of whether or not the power failure monitoring signal is on. Further, when the power failure monitoring signal is kept on for the number of checks (step S38; Y), that is, when it is determined that a power failure has occurred, processing for temporarily prohibiting interruption (step S39), all Processing for outputting off data to the output port is performed (step S40).

  Thereafter, the power failure inspection region check data 1 is saved in the power failure inspection region 1 (step S41), and the power failure inspection region check data 2 is saved in the power failure inspection region 2 (step S42). Further, after performing a checksum calculation process (step S43) for calculating a checksum when the RWM is turned off and a process for saving the calculated checksum in the checksum area (step S44), access to the RAM is prohibited. After performing the process (step S45), it waits for the power supply of the gaming machine to be cut off. In this way, the check data is saved in the power failure inspection area and the checksum at the time of power shutoff is calculated to determine whether the information stored in the RWM before the power shut down is properly backed up. It can be determined at the time of re-input.

  From the above, the main control means (game control apparatus 100) for overall control of the game, and the slave control means (payout control apparatus 200, effect control apparatus 300) for performing various controls in accordance with instructions from the main control means. Etc.), the main control means, when turning on the power, delays the activation of the main control means and sets a predetermined waiting time for waiting for the activation of the slave control device (game control) Device 100) and a power failure monitoring means (game control device 100) for monitoring the occurrence of a power failure during the predetermined waiting time.

  The power supply device 400 includes a power supply device 400 that supplies power to various devices. The power supply device 400 is configured to output a power failure monitoring signal when the occurrence of a power failure is detected, and the power failure monitoring means (game control device 100) When the power failure monitoring signal is continuously received over a predetermined period, it is determined that a power failure has occurred.

  In addition, the main control means (game control device 100) has the RAM 111C capable of storing data, the initialization operation unit (RAM initialization switch 112) capable of being operated from the outside, and the initialization operation unit being operated. And an initialization means (game control device 100) for initializing the data stored in the RAM 111C based on the operation state of the initialization means before the start of the waiting time.

Further, the main control means (game control apparatus 100) permits access to the RAM 111C after the standby time has elapsed.
[Checksum calculation processing]
FIG. 8 is a flowchart illustrating the checksum calculation process according to the first embodiment. This checksum calculation process is a checksum calculation process (steps S19 and S43) in the main process described above. In this checksum calculation process, first, the start address of the RAM is set as the start value of the calculated address (step S101), and the number of repetitions is set (step S102). Here, the number of repetitions is the number of bytes of the RAM used. Next, “0” is set as the calculated value (step S103).

  Thereafter, a value obtained by adding the calculated value to the content of the calculated address is set as a new calculated value (step S104), the calculated address is updated by “+1” (step S105), and the repetition number is updated by “−1” (step S106). ), It is determined whether or not the checksum calculation has been completed (step S107). If the calculation has not been completed (step S107; N), the process returns to step S104 and the above process is repeated. If the calculation is completed (step S107; Y), the checksum calculation process ends.

[Initial value random number update processing]
FIG. 9 is a diagram illustrating a flowchart of initial value random number update processing according to the first embodiment. This initial value random number update process is the initial value random number update process (step S35) in the main process described above. In this initial value random number update process, first, the big hit symbol initial value random number is updated by “+1” (step S111), the small hit symbol initial value random number is updated by “+1” (step S112), and the hit initial value random number is changed to “+1”. Is updated (step S113), and the winning symbol initial value random number is updated by "+1" (step S114), and the initial value random number update process is terminated. Here, the “big hit symbol initial value random number” is a random number that is the initial value of the random number that determines the big hit stop symbol of the special figure, and the “small hit symbol initial value random number” is a random number that determines the small hit symbol stop symbol of the special figure It is a random number that becomes the initial value of. Also, the “hit initial value random number” is a random number that is the initial value of a random number that determines the hit of the normal variation game, and the “hit symbol initial value random number” is the initial value of the random number that determines the hit symbol of the normal variation game Is a random number. The small hit design random number does not exist in a model without small hits, and the hit design initial value random number may not exist depending on the model. In this way, the randomness of the random number can be improved by continuing to increment the initial value random number as long as time permits in the main process.

[Timer interrupt processing]
Next, timer interrupt processing in the above-described main processing will be described. FIG. 10 is a diagram illustrating a flowchart of timer interrupt processing according to the first embodiment. This timer interrupt process is an interrupt process that occurs during the period from when the interrupt is permitted until the interrupt is prohibited (steps S34 to S39) in the main process described above. The timer interrupt process is a process executed by the CPU 111A.

  The timer interrupt process is started when a periodic timer interrupt signal generated by the CTC circuit in the clock generator is input to the CPU 111A. When a timer interrupt occurs in the gaming microcomputer 111, the interrupt is automatically disabled and timer interrupt processing is started.

  When the timer interrupt process is started, first, register bank 1 is designated (step S121). Switching to the register bank 1 is equivalent to performing a register saving process in which a value held in a predetermined register (for example, a register used in the main process) is transferred to the RWM. Next, the upper address of the RAM head address is set in a predetermined register (for example, D register) (step S122). In step S122, the same process as step S4 in the main process is performed, but the register bank is different. Next, input processing (step S123) is performed to input from various sensors and switches and to acquire signals, that is, to read the state of each input port. Then, based on the output data set in various processes, an output process (step S124) for performing drive control of actuators such as solenoids (large winning opening solenoid 38b, general electric solenoid 37c) and the like is performed. In addition, when the signal for stopping the emission is output in step S5 in the main process, the output permission signal is output by performing this output process, and the emission permission signal can be set to the permitted state. This launch permission signal is output to the launch control device via the payout control device. At that time, no signal processing or the like is performed. Further, the launch permission signal is a first signal indicating a launch permission state viewed from the game control device 100, and a second signal (launch permission signal) indicating a launch permission state viewed from the payout control device 200. Is also generated in the payout control device 200 and output to the launch control device. That is, when two launch permission signals are output to the launch control device and both are permitted to launch, the game ball can be launched.

  Next, a payout command transmission process (step S125), a random number update process 1 (step S126), and a random number update process 2 (step S127) for outputting the command set in the transmission buffer in various processes to the payout control apparatus 200 are performed. After that, it is monitored whether there is a normal signal input from the start port 1 switch 36a, the start port 2 switch 37a, the usual gate switch 34a, the winning port switch 35a, and the big winning port switch 38a, and error monitoring ( A prize opening switch / state monitoring process (step S128) is performed to check whether the front frame 12 and the glass frame 15 are open. Also, a special figure game process (step S129) for performing a process relating to the special figure variation display game and a general figure game process (step S130) for performing a process relating to the common figure variation display game are performed.

  Next, a segment LED editing process (step S131) that is provided in the gaming machine 10 and drives a segment LED that displays special information variation display game and various information related to the game to display desired contents, and the magnetic sensor 61. Fraud monitoring process to check whether there is any abnormality by checking the detection signal from the board (step S132), fraudulent board radio wave to check the detection signal from the panel radio wave sensor 62 and determine whether there is any abnormality A monitoring process (step S133) is performed. Then, external information editing processing (step S134) for setting signals to be output to various external devices in the output buffer is performed, and the timer interrupt processing is terminated.

  Here, in the first embodiment, the process for restoring the interrupt disabled state (that is, the process for allowing the interrupt) and the process for restoring the designation of the register bank (that is, the process for designating the register bank 0) are interrupted. Automatically performed on return (at the end of timer interrupt processing). Depending on the CPU used, there is a gaming machine that needs to instruct execution of processing for restoring the interrupt disabled state and processing for restoring the designation of the register bank.

[Input processing]
Next, details of the input process (step S123) in the above-described timer interrupt process will be described. FIG. 11 is a diagram illustrating a flowchart of input processing according to the first embodiment.

  In this input process, first, the state of the detection signal of the switch taken into the input port 1, that is, the first input port 122 is read (step S141). If there is an unused bit in the 8-bit port, the state of the bit is cleared (step S142), and the state of the read input port 1 is saved (stored) in the switch control area 1 in the RWM (step S142). S143). Next, an address of the input port 2, that is, the second input port 123 is prepared (step S144), an address of the switch control area 2 in the RWM is prepared (step S145), and unused bit data is prepared (step S146). Unused bit data and bit data to be inverted are prepared for each input port. Next, bit data to be inverted is prepared (step S147), and switch reading processing (step S148) is performed. Here, “preparation” in the first embodiment means setting a value in a register, but is not limited thereto, and a value may be set in an RWM or other memory.

  Next, the address of the input port 3, that is, the third input port 124 is prepared (step S149), the address of the switch control area 3 in the RWM is prepared (step S150), and unused bit data is prepared ( Step S151), bit data to be inverted is prepared (Step S152). Then, a switch reading process (step S153) is performed, and the input process is terminated.

  As shown in FIG. 3, the switches monitored by the first input port 122 include a glass frame opening detection switch 63, a body frame opening detection switch 64, a RAM initialization switch 112 (unused in this process), There are a power failure monitoring signal (unused in this process) generated by the control signal generation unit 430 of the power supply apparatus 400, a payout abnormality status signal, a shot ball break switch signal, an overflow switch signal, and a touch switch. As a switch to be monitored by the second input port 123, the start port 1 switch 36a (“start port 1 winning signal”) and the start port 2 switch 37a (by pattern branching, “start port 2 winning signal” “normal electric accessory 1”). Also output as winning signal 1 ”), winning port switch 35a (“ ordinary winning port winning signal ”), large winning port switch 38a (“ special electric accessory 1 winning signal ”) and gate switch 34a (“ regular symbol 1 related signal ”). There is a gate passing signal 1 "). The switches monitored by the third input port 124 include a panel radio wave sensor 62, a switch abnormality detection signal, a magnetic sensor 61, a frame radio wave illegal signal, and a payout busy signal.

[Switch read processing]
Next, details of the switch reading process (steps S148 and S153) in the above-described input process will be described. FIG. 12 is a flowchart illustrating the switch reading process according to the first embodiment. In this switch reading process, first, the state of the signal taken into the target input port is read (step S161). If there is an unused bit in the 8-bit port, the state of the bit is cleared (step S162), and the bit that needs to be inverted is inverted (step S163), and then the port input state 1 of the target switch control area Is saved (stored) (step S164). Thereafter, it waits for the delay time (about 100 μs) until the second reading to elapse (step S165).

  When the delay time (about 100 μs) elapses, a second reading of the state of the signal taken into the target input port is performed (step S166). If there is an unused bit in the 8-bit port, the state of the bit is cleared (step S167), the bit that needs to be inverted is inverted (step S168), and then the port input state 2 of the target switch control area Is saved (stored) (step S169). After that, a definite bit pattern in which the same bit is 1 in the first and second readings and a different bit is 0 is created (step S170), and a logical product of the definite bit pattern and port input state 2 is calculated. The confirmation bit is set (step S171).

  Next, an undetermined bit pattern is created by setting the same bit in the first and second readings to 0 and different bits to 1 (step S172), and the logic between the undetermined bit pattern and the final state at the previous interrupt The product is taken and used as the previous retained bit (step S173). As a result, it is possible to obtain a signal state from which noise due to chattering of the switch or the like is removed. Then, the current fixed bit and the previous held bit are combined and saved as the current finalized state (step S174), the exclusive OR of the previous time and the current finalized state is taken and saved as the rising edge (step S175), The switch reading process ends.

  In addition, when the timer interrupt cycle is short (for example, 2 ms), the switch reading is performed once for each interrupt processing, and the signal changes by comparing the result with the previous reading. There is a method of determining whether or not the switch has been made. However, if the switch state read by the previous interrupt is lost before the next interrupt processing, the correct determination may not be performed. On the other hand, as described in the first embodiment, it is possible to avoid the above-described problems by performing the switch reading process twice in one interrupt process with a predetermined time difference. Become.

[Output processing]
Next, details of the output process (step S124) in the above-described timer interrupt process will be described. FIG. 13 is a diagram illustrating a flowchart of output processing according to the first embodiment. In this output process, first, off data is output (reset) to the third output port 135 (see FIG. 3) that outputs the segment data of the batch display device 50 (step S181). Next, the data to be output to the second output port 134 that outputs the data of the ordinary electric solenoid 37c and the big prize opening solenoid 38b is synthesized and output (step S182).

  Then, the value of the digit counter for sequentially scanning the digit lines of the batch display device 50 is updated by “+1” in the range of “0” to “3” (step S183), and the digit of the LED corresponding to the value of the digit counter Line output data is acquired (step S184). Here, as an example of dynamically turning on LED_00 to LED_31 of the collective display device 50, round display, special figure 1 hold display, special figure 1 symbol display, special figure 2 symbol display, universal figure display, universal figure hold display, and There is a state display (game state display such as a short time state or a high probability state).

  Next, the acquired data and external information data are combined (step S185), and the combined data is output to the fourth output port 136 for digit output and the fifth output port 137 for output of external information (step S186). The external information synthesized in step S185 is “door / frame open” and “security signal”.

  Thereafter, the segment line output data is loaded from the segment area in the RWM corresponding to the value of the digit counter (step S187), and the loaded data is output to the third output port 135 for segment output (step S188).

  Subsequently, various output data of external information to be output to the external information terminal board 71 is loaded and combined (step S189). The external information to be synthesized here includes “hit signal 1”, “hit signal 2”, “hit signal 3”, “hit signal 4”, “symbol determined number signal”, “start-up signal”, “main prize ball” Signal "and the like. Next, the synthesized data and the output data for permission to fire are synthesized (step S190), and the synthesized data are output to the fifth output port 137 for outputting external information and for outputting the permission permission signal (step S191).

  Next, the data to be output to the test signal output port 1 on the relay board 70 that outputs the test signal to the test firing test apparatus is loaded and synthesized, and the synthesized data is output to the test signal output port 1 on the relay board 70. (Step S192). Thereafter, the data output to the test signal output port 2 on the relay board 70 that outputs the test signal to the test firing test apparatus is loaded and synthesized, and the synthesized data is output to the test signal output port 2 on the relay board 70. (Step S193).

  Next, the data output to the test signal output port 3 on the relay board 70 that outputs the test signal to the test firing test apparatus is loaded and synthesized, and the synthesized data is output to the test signal output port 3 on the relay board 70. (Step S194). Further, the data to be output is loaded and synthesized to the test signal output port 4 on the relay board 70 that outputs the test signal of the test firing test apparatus, and the synthesized data is outputted to the test signal output port 4 on the relay board 70 ( Step S195). Then, the data output to the test signal output port 5 on the relay board 70 that outputs the test signal to the test firing test apparatus is loaded and synthesized, and the synthesized data is output to the test signal output port 5 on the relay board 70. (Step S196) and the output process is terminated.

[Payout command transmission processing]
Next, details of the payout command transmission process (step S125) in the above-described timer interrupt process will be described. FIG. 14 is a diagram illustrating a flowchart of a payout command transmission process according to the first embodiment. In this figure, the left column is a process for updating (increasing) the number of outputs of the main prize ball signal, and the right column is a process for transmitting a payout command.

  In the payout command transmission process, first, each of the plurality of winning number counter areas provided for each number of prize balls (for example, three prize balls, ten prize balls, and 14 prize balls), which is to be checked. It is determined whether or not there is a count number other than “0” in the winning number counter area 2 storing up to 255 winnings (step S201). If there is no count number (step S201; N), the address of the winning counter area 2 to be checked is updated (step S202), and whether or not the counting of all the winning counter areas has been checked. Is determined (step S203).

  If it is determined in step S201 that there is a count number (step S201; Y), the count number in the target winning number counter area is subtracted ("-1" is updated) (step S204). The number of payouts corresponding to the address is acquired (step S205). Next, the value in the prize ball remaining area and the number of payouts are added (step S206), the addition result is saved in the prize ball remaining area (step S207), and 10 is subtracted from the addition result (step S208). It is determined whether the subtraction result is “0” or more (step S209). If it is determined in step S209 that the subtraction result is equal to or greater than “0” (step S209; Y), the main prize ball signal output count is updated by “+1” (step S210), and the subtraction result is saved in the prize ball remaining area. (Step S211). Here, as a prize ball signal (main prize ball signal), one pulse is output from the main board (game control device 100) for every 10 payout schedules, and 10 payouts are issued from the payout board (payout control device 200). One pulse is output every time.

  Next, it is determined in step S203 that all checks have been completed (step S203; Y), or in step S209, it is determined that the subtraction result is not greater than “0” (step S209; N). If the value of the payout command transmission timer is not “0”, the value of the payout command transmission timer is updated by “−1” (step S212). If the payout command transmission process is the first timer interrupt process, the initial value set in the last step S221 of the payout command transmission process is not set, so the value of the payout command transmission timer is “0”. Therefore, no subtraction is performed. In this way, the payout command is not sent every timer interrupt, but is sent after a predetermined time has elapsed. In addition, the payout command is transmitted under the condition that the payout control board can pay out the winning ball.

  Next, it is determined whether or not the value of the payout command transmission timer is “0” (step S213). When the value of the payout command transmission timer is determined to be “0” (step S213; Y), It is determined whether or not the payout busy signal is busy (step S214). Whether or not the payout busy signal is busy is determined not by referring to the state of the port but by referring to the payout busy signal flag. Here, the conditions that the payout busy signal is turned on (busy) are as follows: “Payout operation”, “Ball lending operation”, “Shoot ball breakage error”, “Overflow error”, “Frame radio wave fraud "In", "Dispensing ball detection switch is abnormal (switch that monitors the dispensed ball)", "Insufficient payout error", "Excessive payout error", "Prize to be paid out in the memory of the payout control board" When there is a count of the number of balls (the number of unpaid prize balls = the number of game balls remaining) (when not = 0).

  Next, when the payout busy signal is not busy (step S214; N), it is determined whether or not there is a count in the winning number counter area 1 (step S215), and if there is no count in the winning number counter area 1 (step S215). N), the address of the winning counter area 1 to be checked is updated (step S216), and it is determined whether or not all areas have been checked (step S217). If all areas have not been checked (step S217; N), the process returns to step S215.

  In step S215, when there is a count in the winning number counter area 1 (step S215; Y), the target winning number counter is updated by "-1" (step S218), and the number of payouts corresponding to the address of the winning number counter area 1 is updated. The command is acquired (step S219), and the acquired command is written in the payout serial transmission buffer (step S220). Then, an initial value (for example, 200 ms) is saved in the payout command transmission timer area (step S221).

  When it is determined in step S213 that the value of the payout command transmission timer is not “0” (step S213; N), the payout busy signal is determined to be busy (step S214; Y) in step S214. In step S217, when it is determined that all areas have been checked (step S217; Y), or when the process of step S221 is completed, the payout command transmission process is terminated.

[Random number update process 1]
Next, the random number update process 1 (step S126) in the timer interrupt process (see FIG. 10) will be described. FIG. 15 is a diagram illustrating a flowchart of the random number update process 1 according to the first embodiment. The random number update process 1 is a process for updating the initial value (start value) of the big hit symbol random number, the small hit symbol random number, the hit random number, and the hit symbol random number that are the targets of the initial value random number update process.

  In this random number update process 1, it is first determined whether or not the normal jackpot symbol random number is waiting for the next initial value (start value) setting (step S231). When the usual big hit symbol random number is not waiting for the initial value setting (step S231; N), it is determined whether the small hit symbol random number is waiting for the next initial value (start value) setting (step S234). Further, when the normal jackpot symbol random number is waiting for the initial value setting (step S231; Y), the jackpot symbol initial value random number is loaded as the next initial value (step S232), and the next time of the loaded bonus symbol random number symbol random number next time Is set in a register (start value setting register) that holds the start value of the corresponding random number counter (random number area) (step S233). Thereafter, it is determined whether or not the small hit design random number is waiting for the next initial value (start value) setting (step S234).

  If the small hit symbol random number is not waiting for the initial value setting (step S234; N), it is determined whether the hit random number is waiting for the next initial value (start value) setting (step S237). If the small hit symbol random number is waiting for initial value setting (step S234; Y), the small hit symbol initial value random number is loaded as the next initial value (step S235), and the next initial value of the loaded small hit symbol random number is set. Is set in a register (start value setting register) that holds the start value of the corresponding random number counter (random number region) (step S236). Thereafter, it is determined whether or not the winning random number is waiting for the next initial value (start value) setting (step S237).

  If the winning random number is not waiting for the initial value setting (step S237; N), it is determined whether or not the winning design random number is waiting for the next initial value (start value) setting (step S240). If the winning random number is waiting for the initial value setting (step S237; Y), the winning initial value random number is loaded as the next initial value (step S238), and the next initial value of the loaded winning random number is set to the corresponding random number counter ( It is set in a register (start value setting register) that holds the start value of the random number area (step S239). Thereafter, it is determined whether or not the winning design random number is waiting for the next initial value (start value) setting (step S240).

  If the winning design random number is not waiting for the initial value setting (step S240; N), the random number update processing 1 is terminated. If the winning design random number is waiting for the initial value setting (step S240; Y), the winning design random number is loaded as the next initial value (step S241), and the next initial value of the loaded winning design random number corresponds. A register (start value setting register) that holds the start value of the random number counter (random number area) is set (step S242), and the random number update process 1 is terminated.

[Random number update process 2]
Next, the random number update process 2 (step S127) in the timer interrupt process (see FIG. 10) will be described. FIG. 16 is a diagram illustrating a flowchart of the random number update processing 2 according to the first embodiment. This random number update process 2 is a process for updating the fluctuation pattern random number for determining the fluctuation pattern in the fluctuation display game of the special figures 1 and 2. In the gaming machine 10 of the first embodiment, there are 1-byte random numbers (variation pattern random numbers 2, 3) and 2-byte random numbers (variation pattern random number 1) as the variation pattern random numbers. Is updated, and the update target is switched every time an interrupt occurs. In addition, when the random number to be updated is 2 bytes, the update process is performed at the time of different interrupts for the upper byte and the lower byte. That is, the update of the 2-byte variation pattern random number 1 (reach variation mode determining random number) by the random number update processing 2 executed in one interrupt processing for the main processing is executed for either the upper 1 byte or the lower 1 byte. It is comprised so that.

  In this random number update process 2, first, a random number update scan counter for designating in order which random number of a plurality of random numbers to be updated is the target of the current update process is changed from “0” to “3”. The range is updated (step S251). Next, the address of the production random number update table corresponding to the value of the random number update scan counter is calculated (step S252). Then, a random number upper limit determination value is acquired from the table referred to based on the calculated address (step S253). The table to be referred to at this time stores an upper limit determination value for each type of random number, that is, a value for determining whether or not the random number has made a round.

  Subsequently, for example, a random counter such as a counter (hereinafter referred to as an M1 counter) used for DRAM refresh or the like provided in the Z80 microcomputer used as the gaming microcomputer 111 in the first embodiment. The value of the counter for which a correct value is set is loaded (step S254). By using the value of the M1 counter, randomness can be given to the random number. Next, a mask value for masking the value of the M1 counter is acquired, and the value of the M1 counter is masked (step S255). The mask value is a bit number that varies depending on the random number to be updated. For example, when the lower 1 byte of the fluctuation pattern random number 1 is updated, the lower 3 bits of the M1 counter and the upper 1 byte of the fluctuation pattern random number 1 Is updated to the lower 4 bits of the M1 counter. This is because the upper limit varies depending on the type of random number. As a mask value, when the lower 1 byte of the fluctuation pattern random number 1 is updated, the lower 3 bits of the M1 counter are updated. Although 4 bits have been exemplified, the numerical value is an example and the present invention is not limited to this.

  Next, it is determined whether or not the random number area (random number counter) to be updated is the upper 1 byte of the 2-byte random number (step S256). Then, if the random number area is the upper 1 byte of the 2-byte random number (step S256; Y), the remaining value by masking the value of the M1 counter with the upper 1 byte as the addition value using the mask value (hereinafter, this is masked). Is set to a mask update value obtained by adding “1” to “0”, the lower 1 byte is set to “0” (step S257), and the process proceeds to step S259. If the random number area is not the upper 1 byte of the 2-byte random number (step S256; N), the upper 1 byte is set to “0” as the addition value, and the lower 1 byte is set to the mask update value (step S258). ), The process proceeds to step S259. Note that “1” is added to the masked value because the masked value may be “0”, and if “0” is added later, it does not change from the value before the addition, so this is avoided. is there.

  Then, it is determined whether or not the random number to be updated is a 2-byte random number (step S259). If it is a 2-byte random number (step S259; Y), the value (2 bytes) of the random number area to be updated is set ( Step S260) and the process proceeds to Step S262. If the random number to be updated is not a 2-byte random number (step S259; N), “0” is set as the upper 1 byte of the random value, and the value of the random number area to be updated (1 byte) as the lower 1 byte of the random value. Is set (step S261), and the process proceeds to step S262.

  In step S262, a value obtained by adding the addition value determined in step S257 or S258 to the random value is set as a new random value, and it is determined whether or not the new random value is larger than the upper limit determination value acquired in step S253. (Step S263). If the new random value is not larger than the upper limit determination value (step S263; N), the new random value is saved in the random number area below the 1-byte random number or 2-byte random number (step S265). If the new random value is larger than the upper limit determination value (step S263; Y), a value obtained by subtracting the upper limit determination value from the new random value is set as a new new random value (step S264), and this value is 1 byte. Save in the random number area below the random number or the 2-byte random number (step S265).

  Next, it is determined whether or not the updated random number is a 2-byte random number (step S266). If the updated random number is not a 2-byte random number (step S266; N), the random number update processing 2 is terminated. If it is a 2-byte random number (step S266; Y), a new random number value (or a value when a new random number is calculated again) is saved in the random number area above the 2-byte random number (step S267). Then, the random number update process 2 is finished.

  In this way, the CPU 111A updates the variation pattern random number for determining the variation pattern in the variation display game of FIG. 1 and FIG. Therefore, the CPU 111 </ b> A determines the variation mode (variation pattern) of the special figure variation display game among various random numbers extracted based on the inflow of the game balls into the start area of the start winning opening 36 or the normal variation winning device 37. Random number updating means for updating the fluctuation pattern random number.

[Prize mouth switch / status monitoring process]
Next, the winning opening switch / state monitoring process (step S128) in the timer interrupt process (see FIG. 10) will be described. FIG. 17 is a diagram illustrating a flowchart of a winning opening switch / state monitoring process according to the first embodiment. In the winning mouth switch / status monitoring process, first, a winning mouth monitoring table (for example, a port to which a detection signal from a count switch is input) corresponding to the big winning mouth switch 38a in the big winning mouth (special variable winning device 38). And data indicating the bit position in the port of the signal and the like are stored) (step S271). Next, a fraud & winning monitoring process (step S272) is performed to monitor whether there are frauds (illegal prizes) to be awarded to the big prize opening even though the big prize opening is not open, and to detect normal winnings. .

  Thereafter, a winning opening monitoring table 2 corresponding to the other large winning opening switch 38a in the large winning opening (special variable winning apparatus 38) is prepared (step S273), and it is monitored whether there is an illegal winning and a normal winning is made. The detected fraud & prize winning monitoring process (step S274) is executed. Then, a winning opening monitoring table of the winning opening switch (starting opening 2 switch 37a) in the ordinary electric power system is prepared (step S275), and an illegal & winning monitoring process for monitoring whether there is an illegal winning and detecting a normal winning ( Step S276) is executed.

  Next, a winning opening monitoring table for the winning opening switch (in this case, the starting opening 1 switch 36a and the winning opening switch 35a of the general winning opening 35) that does not require fraud monitoring processing is prepared (step S277), and the winning number is updated. Number counter update processing (step S278) is performed.

  Next, the value of the state scan counter for sequentially specifying which switch or signal among the plurality of switches and signals to be monitored for the error state of the gaming machine 10 is the current monitoring target is “0”. To “3” (step S279). Thereafter, according to the value of the state scan counter, any one of the switch abnormality 1 error output due to the occurrence of disconnection of the connector of the switch, the shot blowout error from the dispensing control device 200, the overflow error from the overflow switch, and the dispensing abnormality error A gaming machine state monitoring table 1 is prepared for setting the monitoring of errors based on kana (step S280). Then, a gaming machine state check process (step S281) for determining whether or not an error has occurred is performed.

  Next, according to the value of the state scan counter, a gaming machine state monitoring table 2 is prepared for setting an error monitoring based on any of the glass frame opening, the body frame opening, the frame radio wave fraud and the touch switch. (Step S282). Then, a gaming machine state check process (step S283) for determining whether or not an error has occurred is performed.

  Next, it is determined whether or not the value of the status scan counter is “0” (step S284). If the value of the status scan counter is not “0” (step S284; N), the winning prize switch / status monitoring is performed. The process ends. In this case, the gaming machine state monitoring table 3 to be referred next does not have a gaming machine state monitoring target. Further, when the value of the state scan counter is “0” (step S284; Y), the gaming machine state based on the switch abnormality 2 error output due to the occurrence of disconnection of the switch connector or the like according to the value of the state scan counter A gaming machine state monitoring table 3 is set for setting the target of monitoring (step S285). Then, a gaming machine state check process (step S286) for determining whether or not an error has occurred is performed, a payout busy signal check process (step S287) is performed, and the winning opening switch / state monitoring process is terminated. The payout busy signal check process is not performed every time, but is executed once every four times, and the remaining three times are passed, so the monitoring is performed with a period of 16 ms.

[Unauthorized & winning monitoring process]
Next, the fraud & prize winning monitoring process (steps S272, S274, S276) in the winning mouth switch / status monitoring process (see FIG. 17) will be described. FIG. 18 is a diagram illustrating a flowchart of fraud & prize winning monitoring processing according to the first embodiment. Each winning mouth monitoring table prepared in the winning mouth switch / error monitoring process includes “data for determining whether there is an input (monitoring switch bit)”, “lower address of fraud monitoring information”, “illegal prize” "Lower address of number area", "Unauthorized winning error notification command", "Unauthorized winning number upper limit (number of fraud occurrence determination)", "Award switch table address" and "Notification timer update information (permission / update)" Assume that information is defined.

  This fraud & prize winning monitoring process is a process performed for the large prize opening switch 38a of the special variable prize winning device 38 and the start opening 2 switch 37a of the normal variable prize winning device 37. With regard to the big prize opening (special variable prize winning device 38) and the ordinary electric power (ordinary variable prize winning device 37), since it is easy to be fraudulently forcibly opening the opening / closing member and inserting the game ball to pay out the winning ball, In addition to monitoring fraud.

  In the fraud & winning monitoring process, first, the fraud monitoring period flag of the winning mouth switch subject to gaming machine state monitoring is checked (step S291), and it is determined whether it is during the fraud monitoring period (step S292). The fraud monitoring period is a period other than during the special gaming state in which the special variable prize winning device 38 is opened when the prize opening switch to be monitored for the gaming machine state is the big prize opening switch 38a. Further, when the winning opening switch to be monitored for the gaming machine state is the start opening 2 switch 37a, it is a period other than the state in which the opening control of the normal variation winning apparatus 37 is being executed based on the hit of the usual figure.

  If it is the fraud monitoring period (step S292; Y), it is determined whether or not there is an input to the target prize opening switch (step S293). If there is no input to the target prize opening switch (step S293; N), the target notification timer update information is loaded (step S302). If there is an input to the target winning opening switch (step S293; Y), the number of the target illegal winnings is updated by “+1” (step S294), and the number of illegal winnings after the addition is the number of fraud determinations to be monitored ( For example, it is determined whether the number is 5 or more (step S295).

  Note that the number of determinations is five because, for example, when a large winning opening in an open state is converted to a closed state, a game ball is sandwiched between door members of the large winning opening, and the gaming ball is valid for the count switch period. This is to prevent the player from immediately determining that the player has won a prize or that the signal is noisy when the prize is passed. As a result, it is possible to prevent an unauthorized determination from being easily made until it is not necessarily illegal.

  If it is not equal to or greater than the determined number (step S295; N), a winning monitoring table for the target winning opening switch is prepared (step S300). If the number is equal to or greater than the determination number (step S295; Y), the number of fraudulent winnings is limited to the fraud determination number (step S296), and the initial value is saved in the target fraud winning notification timer area (step S297). Next, a target fraud occurrence command is prepared (step S298), a fraud winning flag is prepared as a fraud flag (step S299), and the prepared fraud flag is compared with the value of the target fraud flag area (step S310). ).

  On the other hand, if it is not the fraud monitoring period (step S292; N), a winning monitoring table of the target winning opening switch is prepared (step S300), and a winning number counter updating process (step S301) for setting a winning ball is performed. Then, the target notification timer update information is loaded (step S302), and whether or not the notification timer is permitted to be updated is determined (step S303). Then, when the update of the notification timer is not permitted (step S303; N), the fraud & prize winning monitoring process ends. Note that information that is not permitted to update the notification timer includes a big prize opening switch 38a. This is because one large winning opening is monitored with two switches. If the timer is updated by monitoring both switches, the timer is updated at double speed, and as a result, the illegal timer times out in half of the specified time. In order to avoid such timer updating, updating at the timing of the big prize opening switch that performs the monitoring process first is prohibited. Further, when update of the notification timer is permitted (step S303; Y) as in the case of the big winning opening switch that performs the monitoring process later and the start opening 2 switch 37a of the normal variation winning apparatus 37, the target notification timer is “0”. Otherwise, “−1” is updated (step S304). The minimum value of the notification timer is set to “0”.

  The update of the notification timer is permitted when the prize opening switch subject to gaming machine state monitoring is one of the big prize opening switches 38a, and when the prize opening switch subject to gaming machine state monitoring is the other big prize opening switch 38a. Is not allowed. As a result, it is possible to prevent the notification timer from being updated twice as much as the unauthorized notification about the special variation winning device 38, and to be up in half of the specified time (for example, 60000 ms). Note that the update of the notification timer is always permitted when the winning opening switch to be monitored for the gaming machine state is the big winning opening switch 38a or the start opening 2 switch 37a.

  Thereafter, it is determined whether or not the value of the notification timer is “0” (step S305). If the value is not “0” (step S305; N), that is, if the time has not expired, fraud & winning monitoring is performed. The process ends. If the value is “0” (step S305; Y), that is, if the time has expired or has already expired, a target fraud cancel command is prepared (step S306), and the fraud winning release flag is set as the fraud flag. Is prepared (step S307). Then, the CPU 111A determines whether or not it is the moment when the value of the notification timer becomes “0” (step S308).

  When it is the moment when the value of the notification timer becomes “0” (step S308; Y), that is, when the value of the notification timer becomes “0” in the current fraud & winning monitoring process, Clear (step S309), and compare the prepared illegal flag with the value of the target illegal flag area (step S310). If the notification timer value is not “0” (step S308; N), that is, if the notification timer value is “0” in the previous fraud & winning monitoring process, the prepared fraud flag is prepared. Is compared with the value of the target fraud flag area (step S310).

  Then, if the prepared fraud flag matches the value of the target fraud flag area (step S310; Y), the fraud & prize winning monitoring process is terminated. If the prepared illegal flag does not match the value of the target illegal flag area (step S310; N), the prepared illegal flag is saved in the target illegal flag area (step S311), and the production command setting process is performed (step S311). Step S312), the fraud & prize winning monitoring process is terminated. Through the above process, the fraud notification command is transmitted to the effect control device 300 when fraud occurs, and the illegal prize fraud cancel command is transmitted to the effect control device 300 along with the fraud cancellation, and the start and end of fraud notification are set. Will be.

[Winner counter update process]
Next, the winning number counter updating process (steps S278 and S301) in the above-described winning opening switch / state monitoring process and fraud & winning monitoring process will be described. FIG. 19 is a diagram illustrating a flowchart of the winning number counter updating process according to the first embodiment. It should be noted that the winning table of the winning opening monitoring table prepared in the winning opening switch / status monitoring process includes “repetition count” information and “data for determining whether or not there is an input” defined for each switch. (Monitor switch bit) ”,“ Lower address of the winning number counter area 1 ”and“ Lower address of the winning number counter area 2 ”are defined.

  In this winning number counter updating process, first, the number of winning port switches to be monitored is acquired from the winning port monitoring table (step S321), and whether or not there is an input to the target winning port switch (more precisely, an input change). Is determined (step S322).

  If there is no input (step S322; N), the table address is updated to the address of the next record (step S331). If there is an input (step S322; Y), the value of the target prize counter area 1 is loaded (step S323), the loaded value is updated by "+1" (step S324), and it is determined whether an overflow occurs. (Step S325). If no overflow has occurred (step S325; N), the updated value is saved in the winning number counter area 1 (step S326). As a result, the winning number counter for the winning ball (sending command transmission) is updated. The counter size at this time is 2 bytes, and is updated in the range of “0” to “65535”. If an overflow has occurred (step S325; Y), the process of step S326 is passed.

  Next, the value of the target winning number counter area 2 is loaded (step S327), the loaded value is updated by "+1" (step S328), and it is determined whether or not an overflow occurs (step S329). If no overflow has occurred (step S329; N), the updated value is saved in the winning number counter area 2 (step S330). Thereby, the winning number counter for the main winning ball signal is updated. The counter size at this time is 1 byte, and is updated in the range of “0” to “255”. If an overflow has occurred (step S329; Y), the process of step S330 is passed.

  In step S331, when the table address is updated to the address of the next record, it is determined whether or not monitoring of all the switches has been completed (step S332). If all the switches have not been monitored (step S332; N), the process returns to the process of determining whether or not there is an input to the target winning opening switch (step S322). When monitoring of all the switches is completed (step S332; Y), the winning number counter updating process is terminated. With the above processing, a winning ball corresponding to the winning is set.

[Game machine status check processing]
Next, the gaming machine state check process (step S286) in the above-described winning opening switch / state monitoring process will be described. FIG. 20 is a diagram illustrating a flowchart of the gaming machine state check process according to the first embodiment. Each gaming machine status monitoring table prepared in the winning opening switch / status monitoring process includes “the lower address of the start address of the status monitoring area” and “the port of the switch control area where the target signal information is stored. "Lower address of the input status area", "Mask data to extract only the bit of the target signal", "Signal ON judgment data", "Status OFF command (in the case of error system, meaning of error notification end command)", Information of “status on command (meaning error notification start command in case of error system)”, “status off monitoring timer comparison value”, and “status on monitoring timer comparison value” is defined respectively.

  In this gaming machine state check process, first, a state monitoring table corresponding to the state scan counter is acquired (step S341), and it is determined whether or not the monitoring target signal is on, that is, whether or not it is in a state indicating an error. Determination is made (step S342). The case where the signal to be monitored is not on means that the error system is a normal state that is not an error, and the touch switch is a state that is not touched. Further, the case where the signal to be monitored is ON means an error (abnormal or illegal) state with respect to an error system, and a touch state with respect to a touch switch.

  In step S342, if the signal is not on (step S342; N), a state off flag is prepared as a state flag (step S343), and a target state off command is acquired and prepared (step S344). Thereafter, a target state-off monitoring timer comparison value is acquired (step S345), and the value of the target signal control region is compared with the current signal state (step S349).

  On the other hand, if the signal is on (step S342; Y), a state on flag is prepared as a state flag (step S346), and a target state on command is acquired and prepared (step S347). Thereafter, a target state ON monitoring timer comparison value is acquired (step S348), and the value of the target signal control region is compared with the current signal state (step S349).

  If the value of the target signal control area matches the current signal state (step S349; Y), that is, if the signal state has not changed, the target state monitoring timer is updated by “+1” (step S352). ), It is determined whether or not the value of the target state monitoring timer is equal to or greater than the monitoring timer comparison value (step S353). If the value of the target signal control area does not match the current signal state (step S349; N), that is, if the signal state changes, the current signal state is saved in the target signal control area. (Step S350). Then, the target state monitoring timer is cleared (step S351), the target state monitoring timer is updated by “+1” (step S352), and it is determined whether or not the value of the target state monitoring timer is equal to or greater than the monitoring timer comparison value. (Step S353).

  If the value of the target state monitoring timer has not reached the monitoring timer comparison value (step S353; N), this gaming machine state check process is terminated. If the value of the target state monitoring timer is equal to or greater than the monitoring timer comparison value (step S353; Y), the state monitoring timer is updated by "-1" and kept at the value of "comparison value -1" (step S354). The prepared state flag is compared with the value of the target state flag area (step S355).

  When the prepared state flag matches the value of the target state flag area (step S355; Y), the gaming machine state check process is terminated. If the prepared state flag and the value of the target state flag area do not match (step S355; N), the prepared state flag is saved in the target state flag area (step S356), and the state prepared above is turned off. An effect command setting process for transmitting either a command or a state on command is performed (step S357), and the gaming machine state check process is terminated.

[Payout busy signal check processing]
Next, the payout busy signal check process (step S287) in the above-described winning opening switch / state monitoring process will be described. FIG. 21 is a diagram illustrating a flowchart of the payout busy signal check process according to the first embodiment.

  In this payout busy signal check process, it is first determined whether or not the payout busy signal is on (step S361). If the payout busy signal is not on (step S361; N), an idle state flag is prepared as a state flag ( In step S362), an OFF confirmation monitoring timer comparison value is set (step S363). For example, 32 ms is set as the OFF confirmation monitoring timer comparison value set here.

  In step S361, when the payout busy signal is ON (step S361; Y), a busy state flag is prepared as a state flag (step S364), and an ON confirmation monitoring timer comparison value is set (step S365). For example, 32 ms is set as the ON confirmation monitoring timer comparison value set here.

  Next, the value of the busy signal state area is compared with the state of the current signal (step S366). When the value of the busy signal state area matches the state of the current signal (step S366; Y), that is, when the signal state has not changed, the busy signal monitoring timer is updated by “+1” (step S369). It is determined whether the value of the busy signal monitoring timer is equal to or greater than the timer comparison value (step S370). If the value of the busy signal state area does not match the state of the current signal (step S366; N), that is, if the state of the signal changes, the state of the current signal is saved in the busy signal state area ( Step S367). Then, the busy signal monitoring timer is cleared to zero (step S368), the busy signal monitoring timer is updated by "+1" (step S369), and it is determined whether the value of the busy signal monitoring timer is equal to or greater than the timer comparison value (step S370). ).

  If the value of the busy signal monitoring timer has not reached the timer comparison value (step S370; N), the payout busy signal check process is terminated. If the value of the busy signal monitoring timer becomes equal to or greater than the timer comparison value (step S370; Y), the busy signal monitoring timer is updated by "-1" and kept at the value of "comparison value -1" (step S371). The prepared state flag is saved in the payout busy signal flag area (step S372), and the payout busy signal check process is terminated.

[Special Figure Game Processing]
Next, details of the special game process (step S129) in the timer interrupt process described above will be described with reference to FIG. FIG. 22 is a diagram illustrating a flowchart of special figure game processing according to the first embodiment.

  In the special figure game process, the input of the start port 1 switch 36a and the start port 2 switch 37a is monitored, the entire process related to the special figure variation display game is controlled, and the special figure display is set. In the special figure game process, first, a start port switch monitoring process (step A1) for monitoring the winning of the start port 1 switch 36a and the start port 2 switch 37a is performed. In the start port switch monitoring process, when a game ball is won in the start winning port 36 forming the first start winning port and the normal variable winning device 37 forming the second start winning port, various random numbers (such as big hit random numbers) are extracted. The game result pre-determination is performed in which the game result based on the winning is determined in advance at the stage before the start of the special figure variation display game based on the winning.

  Next, a special winning opening switch monitoring process (step A2) is performed. In this special winning opening switch monitoring process, processing for monitoring the detection of a game ball at the special winning opening switch 38a (large winning opening switch 1, large winning opening switch 2) provided in the special variable winning apparatus 38 is performed.

  Next, if the special figure game processing timer is not "0", "-1" is updated (step A3). The minimum value of the special figure game processing timer is set to “0”. Then, it is determined whether or not the value of the special figure game process timer is “0” (step A4). When the value of the special figure game process timer is “0” (step A4; Y), that is, when time is up or has already expired, reference is made to branch to the process corresponding to the special figure game process number. The special figure game sequence branch table to be set is set in the register (step A5), and the branch destination address of the process corresponding to the special figure game process number is acquired using the table (step A6). Then, a subroutine call is made according to the special figure game process number (step A7).

  In step A7, when the special figure game process number is “0”, the fluctuation start of the special figure fluctuation display game is monitored, the fluctuation start setting of the special figure fluctuation display game, the setting of the production, A special figure routine process (step A8) for setting information necessary for the process is performed.

  In step A7, when the special figure game process number is “1”, special figure changing process for setting the special figure stop display time, setting information necessary for performing the special figure display process, etc. (Step A9) is performed.

  In step A7, if the special figure game process number is “2”, if the game result of the special figure fluctuation display game is a big hit, the fanfare command is set according to the type of the big hit, and the big winning opening for each big hit A special chart display process (step A10) is performed for setting the fanfare time according to the release pattern and setting information necessary for performing the fanfare / interval process.

  In step A7, when the special figure game process number is “3”, setting of the opening time of the special winning opening, updating of the number of opening, setting of information necessary for executing the processing during the opening of the special winning opening are performed. Processing during fanfare / interval (step A11) is performed.

  In step A7, when the special figure game process number is “4”, if the big hit round is not the final round, the interval command is set, while if it is the final round, the ending command is set, A special winning opening opening process (step A12) for performing processing for setting information necessary for performing ball processing, etc. is performed.

  In step A7, if the special figure game processing number is “5”, if the big hit round is not the final round, information necessary for performing the fanfare / interval processing is set, while the round is the final round. Processing for setting the time for discharging the remaining balls in the big winning opening, setting of information necessary for performing the big hit end processing, etc. is performed (step A13).

In step A7, when the special figure game process number is “6”, a big hit end process (step A14) for setting information necessary for performing the special figure routine process is performed.
In step A7, when the special figure game process number is “7”, in order to perform the process of setting the opening time / opening pattern of the big winning opening when the small hit occurs, setting the fanfare command, and the process during the small hit A small hitting fanfare process (step A15) for setting necessary information and the like is performed.

  In step A7, if the special figure game process number is “8”, the setting of the information required for performing the small hit action moving process, the small hit end screen command, the small hit remaining ball process, etc. The small hitting process to be performed (step A16) is performed.

If the special figure game process number is “9” in step A7, the small hit remaining ball process (step A17) is performed for setting information necessary for performing the small hit end process.
In step A7, when the special figure game process number is “10”, a small hit end process (step A18) for setting information necessary for performing the special figure routine process is performed.

  Then, after preparing the table for controlling the fluctuation | variation of the special symbol 1 symbol display part 53 (step A19), the symbol fluctuation | variation control process (step A20) which concerns on the special symbol 1 symbol display part 53 is performed. And after preparing the table for controlling the fluctuation | variation of the special figure 2 symbol display part 54 (step A21), the symbol fluctuation control process (step A22) which concerns on the special figure 2 symbol display part 54 is performed, and a special figure game process Exit. On the other hand, if the value of the special figure game process timer is not “0” in step A4 (step A4; N), that is, if the time is not up, the process proceeds to step A19 and the subsequent processes are performed. Do it.

  Note that the small hit is a result mode that does not involve the operation of the condition device, and the big hit is a special result that involves the operation of the condition device. The condition device is activated when a big hit occurs in the special figure fluctuation display game (stop display of the big hit symbol). When the conditional device is activated, for example, a big hit state occurs and a special electric accessory is generated. It means that a specific flag for continuously operating the variable winning device 38 is set (actual accessory continuous operation device is operated). The fact that the condition device does not operate means that the aforementioned flag is not set as in the case of winning a small lottery. The “condition device” may be software means such as a flag that is turned on / off in software as described above, or may be hardware means such as a switch that is electrically turned on / off. In addition, “condition device” is a term generally used in the field of pachinko gaming machines as a device whose operation is a necessary condition for continuous operation of an electric accessory, and the same applies to this specification. It is used as a term having a meaning.

[Starter switch monitoring process]
Next, details of the start port switch monitoring process (step A1) in the above-described special figure game process will be described with reference to FIG. FIG. 23 is a diagram illustrating a flowchart of the start port switch monitoring process according to the first embodiment.

  In the start port switch monitoring process, first, a start port 1 (start winning port 36) winning monitoring table is prepared (step A101), and a hard random number acquisition process (step A102) is performed to determine whether there is a winning at the starting port 1. It is determined whether or not (step A103).

If it is determined in step A103 that there is no winning at the start port 1 (step A103; N), the process proceeds to step A109, and the subsequent processes are performed.
On the other hand, when it is determined in step A103 that there is a winning at the start port 1 (step A103; Y), it is determined whether or not the special drawing is being shortened (medium power support is in progress) (step A104). . Note that the determination in step A104 is based on whether or not the gaming state is being supported by ordinary power, and does not include the level of the probability state in the determination target.

If it is determined in step A104 that the special drawing time is not short (step A104; N), the process proceeds to step A107 and the subsequent processes are performed.
On the other hand, if it is determined in step A104 that the special drawing time is short (step A104; Y), a right-handed instruction notification command is prepared (step A105), and an effect command setting process (step A106) is performed. . That is, if the time is short, regardless of the probability state of the special figure variation display game, a right-handed instruction notification command is prepared (step A105), and an effect command setting process (step A106) is performed. In the case of the gaming machine 10 according to the first embodiment, the start opening 1 (start winning prize opening 36) will not win unless it is left-handed, and the normal variation winning prize apparatus 37 will not win unless it is right-handed. Therefore, the short-time state is a gaming state in which right-handed is more advantageous than left-handed, but when the start port 1 has won a prize during the short-time state (that is, when left-handed during the short-time state). Is configured to transmit a right-handed instruction notification command to the effect control device 300 and to cause the effect control device 300 to issue a notification (warning) to instruct to make a right-hand strike.

  Next, after preparing a table for setting information on hold by the starting port 1 (starting winning port 36) (step A107), a special-purpose starting port switch common process (step A108) is performed.

  Next, a winning opening monitoring table is prepared for the starting port 2 (ordinary variable winning device 37) (step A109), and a hard random number acquisition process (step A110) is performed to determine whether or not there is a winning at the starting port 2. (Step A111).

If it is determined in step A111 that there is no winning at the start port 2 (step A111; N), the start port switch monitoring process is terminated.
On the other hand, when it is determined in step A111 that there is a winning at the start port 2 (step A111; Y), the ordinary electric accessory (ordinary variable winning device 37) is in operation, that is, the normal variable winning. It is determined whether or not the device 37 is in an open state in which a game ball can be won (step A112). If it is determined that the ordinary electric accessory is operating (step A112; Y), step A114 is performed. The process proceeds to the following process. On the other hand, if it is determined in step A112 that the ordinary electric accessory is not in operation (step A112; N), it is determined whether or not a normal electric power fraud has occurred (step A113).

  In determining whether or not the ordinary power fraud is occurring, it is determined that the fraud is occurring when the number of fraudulent winnings to the normal variation winning device 37 is equal to or greater than the number of fraud determination (for example, 5). The normal variation winning device 37 cannot win a game ball in the closed state, and can win a game ball only in the open state. Therefore, when the game ball wins in the closed state, it is a case where some abnormality or fraud has occurred. When there is a game ball won in such a closed state, the number is counted as the number of illegal wins. Then, when the number of illegal winnings counted in this way is equal to or larger than a predetermined fraud occurrence determination number (upper limit value), it is determined that fraud has occurred.

  If it is determined in step A113 that there is no fraudulent power transmission (step A113; N), a table for setting information on hold by the start port 2 (ordinary variable winning device 37) is prepared (step A114). A start port switch common process (step A115) is performed, and the start port switch monitoring process is terminated. If it is determined in step A113 that the power transmission fraud has occurred (step A113; Y), the start port switch monitoring process is terminated. That is, the second start memory is not generated any more.

[Hard random number acquisition processing]
Next, details of the hard random number acquisition processing (steps A102 and A110) in the above-described start port switch monitoring processing will be described with reference to FIG. FIG. 24 is a diagram illustrating a flowchart of hard random number acquisition processing according to the first embodiment.

  In the hard random number acquisition process, first, no winning information is set for the start port to be monitored among the start port 1 (start winning port 36) and the start port 2 (ordinary variable winning device 37) (step A121). It is determined whether or not there is an input to the monitored start port switch among the port 1 switch 36a and the start port 2 switch 37a (step A122). Then, when there is no input to the monitoring target start port switch (step A122; N), the hard random number acquisition process is terminated. On the other hand, when there is an input to the monitoring target start switch (step A122; Y), the random number latch register status is read (step A123), and it is determined whether there is latch data in the target random number latch register (step A123). A124).

  If there is no latch data in the target random number latch register (step A124; N), that is, if no random number has been extracted, the hard random number acquisition process is terminated. If there is latch data in the target random number latch register (step A124; Y), the big hit random number extracted to the monitored hard random number latch register is loaded and prepared (step A125). Then, among the starting port 1 (starting winning port 36) and the starting port 2 (ordinary variable winning device 37), the information indicating that there is a winning for the starting port to be monitored is set (step A126), and the hard random number acquisition process is terminated. .

[Special figure start port switch common processing]
Next, details of the special start port switch common process (steps A108 and A115) in the start port switch monitoring process described above will be described with reference to FIG. FIG. 25 is a diagram illustrating a flowchart of the special chart start port switch common process according to the first embodiment.

The special figure start port switch common process is a process that is commonly performed for each input when there is an input from the start port 1 switch 36a or the start port 2 switch 37a.
In the special figure start port switch common processing, first, information on the number of winnings to the start port switch to be monitored out of the start port 1 switch 36a and the start port 2 switch 37a is sent to the management device outside the gaming machine 10. The start port signal output count that is the output count is loaded (step A131), the loaded value is updated by "+1" (step A132), and it is determined whether the output count overflows (step A133). If the number of outputs does not overflow (step A133; N), the updated value is saved in the starter signal output number area of the RWM (step A134), and the process proceeds to step A135. On the other hand, when the number of outputs overflows (step A133; Y), the process proceeds to step A135 after passing through step A134. In the first embodiment, values from “0” to “255” can be stored in the start port signal output frequency area. When the loaded value is “255”, the updated value becomes “0” when “+1” is updated, and it is determined that the output count overflows.

  Next, it is determined whether or not the number of special figure hold (starting memory) to be updated corresponding to the monitoring target starter switch among the starter 1 switch 36a and the starter 2 switch 37a is less than the upper limit ( Step A135). When the number of special figure reservations to be updated is not less than the upper limit value (step A135; N), the special figure start port switch common process is terminated. If the number of special figure hold to be updated is less than the upper limit (step A135; Y), update the number of special figure hold (number of special figure 1 hold or special figure 2 hold) to be updated by “+1” ( In step A136), the start port winning flag to be monitored is saved (step A137). Subsequently, the address of the random number storage area corresponding to the start port switch to be monitored and the number of special figure hold is calculated (step A138), and the big hit random number prepared in step A125 is saved in the big hit random number storage area of the RWM ( Step A139). Next, the jackpot symbol random number of the starter switch to be monitored is extracted, prepared (step A140), and saved in the jackpot symbol random number storage area of the RWM (step A141).

Next, it is determined whether or not it is a winning to the starting port 1 (starting winning port 36) (step A142).
If it is determined in step A142 that the winning is not for the start port 1 (step A142; N), the process proceeds to step A145.

  On the other hand, if it is determined in step A142 that the winning is to the starting port 1 (step A142; Y), a small hit symbol random number is extracted and prepared (step A143), and the RWM small hit symbol random number is prepared. Save in the storage area (step A144).

  Next, the fluctuation pattern random numbers 1 to 3 are saved in the corresponding RWM fluctuation pattern random number storage area (step A145), and special figure hold information determination processing (step A146) is performed.

  Next, a decoration special figure hold number command corresponding to the start opening switch to be monitored and the special figure hold number is prepared (step A147), a production command setting process (step A148) is performed, and a special figure start opening switch common process is performed. finish.

  Here, the RAM 111C of the game microcomputer 111 of the game control device 100 extracts a predetermined random number based on the inflow of the game ball into the start winning area of the start winning opening 36 or the normal variation winning device 37, and the special variable display game. The start winning storage means for storing a predetermined number as the upper limit as the start storage serving as the right to execute the. Further, the start winning storage means (RAM 111C) stores various random numbers extracted based on the winning of the game ball to the start opening 1 (start winning opening 36) as a first start storage with a predetermined number as an upper limit. Various random numbers extracted based on the winning of the game ball to the mouth 2 (ordinary variable winning device 37) are stored as the second start memory up to a predetermined number.

[Special figure hold information judgment processing]
Next, details of the special figure hold information determination process (step A146) in the above-described start port switch common process will be described with reference to FIG. FIG. 26 is a diagram illustrating a flowchart of special figure hold information determination processing according to the first embodiment.

  The special figure hold information determination process is a look-ahead process for determining the result related information corresponding to the start memory before the start timing of the special figure variation display game based on the corresponding start memory.

  In the special figure hold information determination process, first, the starting port winning flag saved in step A137 is checked to determine whether or not the starting port 1 (starting winning port 36) is winning (step A151).

If it is determined at step A151 that the winning is not for the start port 1 (step A151; N), the process proceeds to step A154 and the subsequent processes are performed.
On the other hand, if it is determined in step A151 that the start port 1 has been won (step A151; Y), it is determined whether or not the special drawing time is short (step A152).

If it is determined in step A152 that the special figure time is short (step A152; Y), the special figure hold information determination process is terminated.
On the other hand, when it is determined in step A152 that the special drawing time is not short (step A152; N), it is determined whether the big hit or the small hit is being made (step A153).

In step A153, when it is determined that the big hit or the small hit is being made (step A153; Y), the special figure holding information determination processing is ended.
On the other hand, when it is determined in step A153 that no big hit or small hit is being made (step A153; N), it is determined whether or not the big hit is a big hit depending on whether or not the big hit random value matches the big hit determination value. A big hit determination process (step A154) is performed.

  Thereafter, it is determined whether or not the determination result of the jackpot determination process is a jackpot (step A155). If the determination result is a big hit (step A155; Y), a big hit symbol random number check table corresponding to the target starter switch is set (step A156), and the big hit symbol random number prepared in step A140 is corresponded. Stop symbol information is acquired (step A157), the process proceeds to step A164, and the subsequent processes are performed.

On the other hand, when the determination result is not a big hit (step A155; N), it is determined whether or not the winning is the starting port 1 (starting winning port 36) (step A158).
If it is determined in step A158 that the winning is not made at the starting port 1 (step A158; N), the stop symbol information of the outage is set (step A163), the process proceeds to step A164, and thereafter Perform the process.

  On the other hand, if it is determined in step A158 that the start port 1 has been won (step A158; Y), whether or not the big hit random number value matches the small hit determination value or not. A small hit determination process (step A159) is performed.

  Thereafter, it is determined whether or not the determination result of the small hit determination process is a small hit (step A160). If the determination result is not a small hit (step A160; N), the stop symbol information of the outage is set (step A163), the process proceeds to step A164, and the subsequent processes are performed.

  On the other hand, if the determination result is a small hit (step A160; Y), a small hit symbol random number check table is set (step A161), and stop symbol information corresponding to the small hit symbol random number prepared in step A143 is obtained. (Step A162), the process proceeds to step A164, and the subsequent processes are performed.

  Then, a pre-read stop symbol command corresponding to the target start opening switch and stop symbol information is prepared (step A164), and an effect command setting process (step A165) is performed. Next, a special figure information setting process (step A166) for setting special figure information which is a parameter for setting a fluctuation pattern is performed, and a fluctuation pattern setting process (step A167) for setting the fluctuation mode of the special figure fluctuation display game. To do.

  Thereafter, a prefetch variation pattern command corresponding to the first half variation number indicating the first half variation pattern and the second half variation number representing the second half variation pattern in the variation mode of the special figure variation display game is prepared (step A168), and an effect command setting process (step A169) is performed, and the special figure hold information determination process is terminated. The special figure information setting process in step A166 and the fluctuation pattern setting process in step A167 are the same as the processes executed at the start of the special figure fluctuation display game in the special figure ordinary process.

  Through the above processing, a prefetch symbol command including the result of the special figure variation display game based on the start memory to be prefetched and a prefetch variation pattern command including information on the variation pattern in the special figure variation display game based on the start memory are prepared. And transmitted to the production control device 300. As a result, the result control (result of prefetching) of the result related information (whether it is a big hit or the type of variation pattern) corresponding to the start memory is effected before the start timing of the special figure variation display game based on the corresponding start memory. The device 300 can be notified, and in particular, by changing the decoration special figure start memory display displayed on the display device 41, the result related information is given to the player before the start timing of the special figure variable display game. It is possible to notify.

  That is, the game control device 100 determines a random number stored as a start memory in the start winning storage means (RAM 111C) before the execution of the variable display game based on the start memory (for example, whether or not a special result is obtained). Judgment) Pre-determination means. Note that the time when the random number value stored in correspondence with the start memory is determined in advance is not only at the time of the start winning when the start memory is generated, but any time before the variable display game based on the start memory is performed. Good.

[Big prize opening switch monitoring process]
Next, the details of the special winning opening switch monitoring process (step A2) in the special figure game process described above will be described with reference to FIG. FIG. 27 is a diagram illustrating a flowchart of the special winning opening switch monitoring process according to the first embodiment.

  In the big prize opening switch monitoring process, first, it is determined whether or not the big prize opening (special variable prize winning device 38) is being opened, that is, whether or not it is in a special gaming state (step A201). When the special winning opening is being opened (step A201; Y), the process proceeds to step A205, and the subsequent processes are performed. If it is not in the process of opening the big winning opening (step A201; N), it is determined whether or not the big winning opening remaining ball is being processed (step A202).

  When the winning prize remaining ball processing is in progress (step A202; Y), the process proceeds to step A205. If it is not in the big winning opening remaining ball processing (step A202; N), it is determined whether or not the small hit (in the small hit gaming state) is being processed (step A203).

  If the small hit process is being performed (step A203; Y), the process proceeds to step A205. When the small hitting is not being processed (step A203; N), it is determined whether the small hit remaining ball is being processed (step A204).

  When the small hit remaining ball processing is not in progress (step A204; N), the big winning opening switch monitoring processing is terminated. If the small hit remaining sphere processing is in progress (step A204; Y), the processing proceeds to step A205.

  Note that the special figure game process number does not shift until the special figure game process timer becomes “0”, so the progress state of the game is checked by checking the special figure game process number value. Can be checked. Therefore, the special figure game process number is checked to determine whether the big winning opening is being opened, the big winning opening remaining ball is being processed, the small hit is being processed, and the small hit remaining ball is being processed. Let's do it.

  Then, “0” is set in the winning counter for counting the number of winning prizes to the winning prize opening added in the current winning prize opening switch monitoring process (step A205). Is determined (step A206).

  If there is no input to the big prize opening switch 1 (step A206; N), the process proceeds to step A210 and the subsequent processes are performed. When there is an input to the big prize opening switch 1 (step A206; Y), a big prize mouth count command is prepared (step A207), an effect command setting process (step A208) is performed, and the value of the prize counter is set to “ +1 "is updated (step A209).

  Then, it is determined whether or not there is an input to the special prize opening switch 2 (step A210). If there is no input to the special prize opening switch 2 (step A210; N), the process proceeds to step A214. The subsequent processing is performed. When there is an input to the big prize opening switch 2 (step A210; Y), a big prize mouth count command is prepared (step A211), an effect command setting process (step A212) is performed, and the value of the prize counter is set to “ +1 "is updated (step A213).

  Then, it is determined whether or not the value of the winning counter is “0” (step A214). If the value of the winning counter is “0” (step A214; Y), the big winning opening switch monitoring process is performed. finish. If the value of the winning counter is not “0” (step A214; N), it is determined whether or not the big winning opening remaining ball processing is being performed (step A215), and if the big winning opening remaining ball processing is being performed (step A215). In step A215; Y), the special winning opening switch monitoring process is terminated.

  When the winning ball remaining ball processing is not being performed (step A215; N), it is determined whether or not the small hit remaining ball processing is being performed (step A216), and if the small hit remaining ball processing is being performed (step A216; In Y), the special winning opening switch monitoring process is terminated.

  If the small hit remaining ball processing is not in progress (step A216; N), the value of the winning counter ("1" or "2") is added to the winning prize count (step A217), and the winning prize count is calculated. It is determined whether or not the upper limit value (the number of game balls that can be won in one round (9)) or more is reached (step A218).

  If the number of the big winning mouth count is not equal to or greater than the upper limit (step A218; N), the big winning mouth switch monitoring process is terminated. If the winning prize count is greater than or equal to the upper limit (step A218; Y), the winning prize count is kept at the upper limit (step A219), and the information in the special figure game processing timer area is cleared to zero (step A220). ), It is determined whether or not the small hitting process is being performed (step A221).

  If it is not under mid-hit processing (step A221; N), the big winning opening switch monitoring process is terminated. When the process is being processed during the small hit (step A221; Y), the value of the end of the small hit release operation is saved in the big winning opening control pointer area (step A222), and the big winning opening switch monitoring process is terminated. This closes the grand prize opening and ends one round.

[Special figure routine processing]
Next, details of the special figure routine process (step A8) in the special figure game process described above will be described with reference to FIG. FIG. 28 is a diagram illustrating a flowchart of the special figure normal processing according to the first embodiment.

  In the special figure routine processing, first, it is determined whether or not the special figure 2 hold number (second start memory number) is “0” (step A301). If it is determined that the special figure 2 hold number is “0” (step A301; Y), it is determined whether or not the special figure 1 hold number (first start memory number) is “0” (step A306). Then, if it is determined that the special figure 1 holding number is “0” (step A306; Y), it is determined whether or not the customer waiting demo has been started (step A311), and the customer waiting demo has not been started. (Step A311; N) sets a customer waiting demo flag in the customer waiting demo flag area (step A312).

  Subsequently, a customer waiting demonstration command is prepared (step A313), an effect command setting process (step A314) is performed, a special figure normal process transition setting process 1 (step A315) is performed, and the special figure normal process is terminated. . On the other hand, if the customer waiting demonstration has been started in step A311, (step A311; Y), special figure normal process transition setting process 1 (step A315) is performed, and the special figure normal process is terminated.

  In step A301, if the special figure 2 hold number is not "0" (step A301; N), a special figure 2 change start process (step A302) is performed, and the decorative special figure corresponding to the special figure 2 hold number is performed. A reservation number command is prepared (step A303), and an effect command setting process (step A304) is performed. Then, the special figure fluctuation mid-process transition setting process (step A305) of special figure 2 is performed, and the special figure ordinary process is terminated.

  In step A306, if the special figure 1 hold number is not "0" (step A306; N), the special figure 1 fluctuation start process (step A307) is performed, and the decorative special figure corresponding to the special figure 1 hold number is performed. A reserve number command is prepared (step A308), and an effect command setting process (step A309) is performed. Then, the special-figure changing process transition setting process (step A310) of special figure 1 is performed, and the special figure usual process is terminated.

  In this way, by checking the special figure 2 hold number before the special figure 1 hold number check, if the special figure 2 hold number is not “0”, the special figure 2 fluctuation start process (step A302). Will be executed. That is, the second special figure variation display game is executed with priority over the first special figure variation display game. In other words, when the game control device 100 has the second start memory in the second start memory means (game control device 100), the variable display game based on the second start memory is displayed as the variable display game based on the first start memory. Priority control means for executing with priority over the game.

[Special figure transition setting process 1]
Next, details of the special figure normal process transition setting process 1 (step A315) in the special figure normal process described above will be described with reference to FIG. FIG. 29 is a diagram illustrating a flowchart of the special figure normal process transition setting process 1 according to the first embodiment.

  In the special figure normal process transition setting process 1, first, “0”, which is a process number related to the special figure normal process, is set as a process number (step A321), and the process number is saved in the special figure game process number area (step S321). A322).

  Then, the information of the variation symbol determination flag area is cleared (step A323), the fraud monitoring period flag is saved in the special prize opening fraud monitoring period flag area (step A324), and the special figure normal process transition setting process 1 is finished. To do.

[Special Figure 1 Change Start Processing]
Next, the details of the special figure 1 variation start process (step A307) in the above-described special figure ordinary process will be described with reference to FIG. FIG. 30 is a diagram illustrating a flowchart of the special figure 1 variation start process of the first embodiment.

  The special figure 1 fluctuation start process is a process performed at the start of the first special figure fluctuation display game. In the special figure 1 variation start process, first, a special figure 1 variation flag indicating the type of special figure variation display game to be executed (here, special figure 1) is saved in the variation symbol discrimination flag area (step A331), and the first special figure variation display game is executed. A jackpot flag 1 setting process (step A332) is performed for setting shift information and jackpot information to the jackpot flag 1 for determining whether or not the figure variation display game is a jackpot.

  Next, after performing the special figure 1 stop symbol setting process (step A333) relating to the setting of the special figure 1 stop symbol (symbol information), the special symbol for setting the special symbol information which is a parameter for setting the variation pattern An information setting process (step A334) is performed to prepare a special figure 1 fluctuation pattern setting information table which is a table in which information for referring to various information related to the setting of the fluctuation pattern of the first special figure fluctuation display game is set. (Step A335). Thereafter, a variation pattern setting process (step A336) for setting a variation pattern which is a variation mode in the first special figure variation display game is performed, and a variation start information setting process for setting variation start information of the first special figure variation display game. (Step A337) is performed, and the special figure 1 fluctuation start process is terminated.

[Special Figure 2 Variation Start Processing]
Next, details of the special figure 2 variation start process (step A302) in the above-described special figure ordinary process will be described with reference to FIG. FIG. 31 is a diagram illustrating a flowchart of special figure 2 variation start processing according to the first embodiment.

  The special figure 2 fluctuation start process is a process performed at the start of the second special figure fluctuation display game, and the same process as the special figure 1 fluctuation start process shown in FIG. It is something to do as.

  In the special figure 2 fluctuation start process, first, a special figure 2 fluctuation flag indicating the type of the special figure fluctuation display game to be executed (here, special figure 2) is saved in the fluctuation symbol discrimination flag area (step A341), and the second special figure fluctuation display game is executed. A jackpot flag 2 setting process (step A342) is performed for setting shift information and jackpot information to the jackpot flag 2 for determining whether or not the figure variation display game is a jackpot.

  Next, after performing the special figure 2 stop symbol setting process (step A343) related to the setting of the special figure 2 stop symbol (symbol information), the special symbol for setting the special symbol information which is a parameter for setting the variation pattern An information setting process (step A344) is performed to prepare a special figure 2 fluctuation pattern setting information table that is a table in which information for referring to various information related to the setting of the fluctuation pattern of the second special figure fluctuation display game is set. (Step A345). Thereafter, a variation pattern setting process (step A346) for setting a variation pattern which is a variation mode in the second special figure variation display game is performed, and a variation start information setting process for setting variation start information of the second special figure variation display game. (Step A347) is performed, and the special figure 2 fluctuation start process is terminated.

[Big hit flag 1 setting process]
Next, the details of the big hit flag 1 setting process (step A332) in the special figure 1 fluctuation start process described above will be described with reference to FIG. FIG. 32 is a diagram illustrating a flowchart of the big hit flag 1 setting process according to the first embodiment.

  In the big hit flag 1 setting process, first, deviation information is saved in the small hit flag area (step A351), and deviation information is saved in the big hit flag 1 area (step A352). Next, a big hit random number is loaded from the RWM special figure 1 big hit random number storage area (for holding number 1), prepared (step A353), and information on the special figure big hit random number storage area (for holding number 1) is stored. “0” is cleared (step A354). Note that for the number of holdings 1 is an area for storing information (random numbers or the like) about the special figure starting storage whose digestion order is the earliest (here, the earliest in the special figure 1). Thereafter, a jackpot determination process (step A355) is performed to determine whether the prepared jackpot random number value matches the jackpot determination value or not, and whether the determination result of the jackpot determination process is a jackpot It is determined whether or not (step SA356).

  If the determination result of the big hit determination process (step A355) is a big hit (step A356; Y), the big hit information is overwritten and saved in the big hit flag 1 area where the loss information was saved in step A352 (step A357). ), The big hit flag 1 setting process is terminated. On the other hand, if the determination result of the big hit determination process (step A355) is not a big hit (step A356; N), whether the prepared big hit random number value matches the small hit determination value or not is a big hit. A small hit determination process (step A358) is performed to determine whether the determination result of the small hit determination process is a small hit (step SA359).

  If the determination result of the small hit determination process (step A358) is a small hit (step A359; Y), the small hit information is overwritten and saved in the small hit flag area in which the loss information is saved in step A351. (Step A360), the big hit flag 1 setting process is terminated. On the other hand, when the determination result of the small hit determination process (step A358) is not a small hit (step A359; N), the big hit flag 1 setting process is performed while saving the deviation information in both the big hit flag 1 area and the small hit flag area. finish. In this way, in the first embodiment, the result of the first special figure variation display game is any one of “big hit”, “small hit”, and “out of game”.

[Big hit flag 2 setting process]
Next, details of the big hit flag 2 setting process (step A342) in the above-described special figure 2 fluctuation start process will be described with reference to FIG. FIG. 33 is a diagram illustrating a flowchart of the big hit flag 2 setting process according to the first embodiment.

  In the big hit flag 2 setting process, first, shift information is saved in the big hit flag 2 area (step A371). Next, a big hit random number is loaded from the RWM special figure 2 big hit random number storage area (for holding number 1), prepared (step A372), and information on the special figure 2 big hit random number storage area (for holding number 1) is stored. “0” is cleared (step A373). Note that for the number of reservations 1 is an area for storing information (random number or the like) about the special figure starting storage whose digestion order is the earliest (here, the earliest in the special figure 2). Thereafter, a jackpot determination process (step A374) is performed to determine whether the prepared jackpot random number value matches the jackpot determination value or not, and whether the determination result of the jackpot determination process is a jackpot It is determined whether or not (step SA375).

  If the determination result of the big hit determination process (step A374) is a big hit (step A375; Y), the big hit information is overwritten and saved in the big hit flag 2 area where the loss information is saved in step A371 (step A376). ), The big hit flag 2 setting process is terminated. On the other hand, if the determination result of the big hit determination process (step A374) is not a big hit (step A375; N), the big hit flag 2 setting process is terminated while the deviation information is saved in the big hit flag 2. As described above, in the first embodiment, the result of the second special figure variation display game is either “big hit” or “out of game”.

[Big hit judgment processing]
Next, details of the jackpot determination process (steps A154, A355, and A374) in the special figure hold information determination process, the jackpot flag 1 setting process, and the jackpot flag 2 setting process described above will be described with reference to FIG. FIG. 34 is a diagram illustrating a flowchart of jackpot determination processing according to the first embodiment.

  In the big hit determination process, first, a lower limit determination value of the big hit determination value is set (step A381), and it is determined whether or not the value of the target big hit random number is less than the lower limit determination value (step A382). The big hit means that the big hit random number matches the big hit determination value. The big hit judgment value is a plurality of consecutive values, and the big hit random number is greater than or equal to the lower limit judgment value that is the lower limit value of the big hit judgment value and less than or equal to the upper limit judgment value that is the upper limit value of the big hit judgment value It is determined that it is a big hit.

  When the value of the big hit random number is less than the lower limit determination value (step A382; Y), the difference is set as the determination result (step A387), and the big hit determination process ends. Specifically, when the jackpot determination process is a jackpot determination process (step A355) in the jackpot flag 1 setting process, if the value of the jackpot random number is less than the lower limit determination value (step A382; Y), Since it is a small hit or miss, “other than big hit (small hit or miss)” is set as the determination result (step A387). On the other hand, when the big hit determination process is the big hit determination process (step A374) in the big hit flag 2 setting process, the case where the value of the big hit random number is less than the lower limit determination value (step A382; Y) is out of place. Therefore, “other than big hit (out of line)” is set as the determination result (step A387).

  If the value of the big hit random number is not less than the lower limit determination value (step A382; N), it is determined whether or not the probability is high (the probability state of the special figure variation display game is the high probability state) (step A383). .

  If the probability is high (step A383; Y), an upper limit determination value with high probability is set (step A384), and it is determined whether or not the value of the target big hit random number is greater than the upper limit determination value ( Step A386). If not in the high probability state (step A383; N), an upper limit determination value with a low probability is set (step A385), and it is determined whether or not the value of the target jackpot random number is larger than the upper limit determination value (step A385). A386).

  When the value of the big hit random number is larger than the upper limit determination value (step A386; Y), the difference is set as the determination result (step A387), and the big hit determination process is terminated. Specifically, when the big hit determination process is the big hit determination process (step A355) in the big hit flag 1 setting process, when the value of the big hit random number is larger than the upper limit determination value (step A386; Y), Since it is a hit or miss, “other than big hit (small hit or miss)” is set as the determination result (step A387). On the other hand, when the big hit determination process is the big hit determination process (step A374) in the big hit flag 2 setting process, the case where the value of the big hit random number is larger than the upper limit determination value (step A386; Y) is out of place. Then, “other than big hit (out)” is set as the determination result (step A387).

  If the value of the big hit random number is not larger than the upper limit determination value (step A386; N), that is, if the big hit is a big hit, the big hit is set as the determination result (step A388), and the big hit determination process is terminated.

[Small hit judgment processing]
Next, details of the small hit determination process (steps A159 and A358) in the special figure hold information determination process and the big hit flag 1 setting process described above will be described with reference to FIG. FIG. 35 is a diagram illustrating a flowchart of the small hit determination process according to the first embodiment.

  As shown in FIG. 35, in the small hit determination process, first, a small hit lower limit determination value is set, and it is determined whether or not the value of the target big hit random number is less than the small hit lower limit determination value (step A391). Note that the small hit determination is performed using the same random number (big hit random number) as the big hit determination. In other words, “small hit” means that the big hit random number matches the small hit determination value. The small hit judgment value is a plurality of consecutive values, and the big hit random number is greater than or equal to the small hit judgment lower limit judgment value that is the lower limit value of the small hit judgment value, and the small hit judgment upper limit that is the upper limit value of the small hit judgment value. When it is less than or equal to the determination value, it is determined to be a small hit. Of course, the range of the big hit judgment value and the range of the small hit judgment value are set so as not to suffer.

  When the value of the big hit random number is less than the small hit lower limit determination value (step A391; Y), that is, when it is out of place, a determination is made as a determination result (step A393), and the small hit determination processing is terminated.

  If the value of the big hit random number is not less than the small hit lower limit determination value (step A391; N), a small hit upper limit determination value is set, and whether or not the target big hit random value is larger than the small hit upper limit determination value is determined. Determine (step A392).

  When the value of the big hit random number is larger than the small hit upper limit determination value (step A392; Y), that is, when it is out of place, the determination result is set as out (step A393), and the small hit determination process is terminated.

  If the value of the big hit random number is not larger than the small hit upper limit determination value (step A392; N), that is, if it is a small hit, the small hit is set as the determination result (step A394), and the small hit determination processing is terminated. To do.

[Special figure 1 stop symbol setting process]
Next, details of the special figure 1 stop symbol setting process (step A333) in the special figure 1 fluctuation start process described above will be described with reference to FIG. FIG. 36 is a diagram illustrating a flowchart of the special figure 1 stop symbol setting process according to the first embodiment.

  In the special figure 1 stop symbol setting process, it is first determined whether or not the big hit flag 1 is a big hit (step A401). If the big hit flag 1 is a big hit (step A401; Y), the special figure 1 big hit symbol random number storage area (the number of holds) 1) is loaded with a jackpot symbol random number (step A402). Next, the special figure 1 big hit symbol table is set (step A403), the stop symbol number corresponding to the loaded big hit symbol random number is acquired, and saved in the special figure 1 stop symbol number area (step A404). By this process, the type of special result is selected.

  After that, the special symbol 1 big hit stop symbol information table is set (step A405), a stop symbol pattern corresponding to the stop symbol number is acquired, and saved in the stop symbol pattern area (step A406). The stop symbol pattern is for setting a stop symbol on the special symbol 1 symbol display unit 53 and a stop symbol on the display device 41. Next, the round number upper limit value information corresponding to the stop symbol number is acquired and saved in the round number upper limit information area (step A407), the time reduction determination data corresponding to the stop symbol number is acquired, and the time reduction determination is acquired. The data area is saved (step A408), and the production mode transition information corresponding to the stop symbol pattern and the probability state is saved (step A409). These pieces of information are for setting the execution mode of the special gaming state and the effect mode after the special gaming state is finished. In the case of the first embodiment, the effect mode shifts in response to a hit, and the transition destination of the effect mode that shifts after the hit ends changes according to the type of winning symbol (type of big hit symbol or small hit). Also, in the case of a special big hit symbol (for example, 4R probability variation symbol) in the special figure 1, the transition-destination effect mode is a certain probability variation confirmation depending on whether or not the gaming state is in certain probability variation. It is determined whether to shift to the production mode, which is difficult to distinguish whether it is the production mode or the probability variation. Then, a special decoration figure command corresponding to the stop symbol pattern is prepared (step A418).

  On the other hand, when the big hit flag 1 is not a big hit (step A401; N), it is determined whether or not the small hit flag is a small hit (step A410). The small hit design random number is loaded from the small hit design random number storage area (for holding number 1) (step A411). Next, the special figure 1 small hit symbol table is set (step A412), the stop symbol number corresponding to the loaded small hit symbol random number is acquired, and saved in the special figure 1 stop symbol number area (step A413).

  Thereafter, a stop symbol pattern corresponding to the stop symbol number is acquired, saved in the stop symbol pattern area (step A414), and effect mode transition information corresponding to the stop symbol pattern is saved (step A415). Then, a special decoration figure command corresponding to the stop symbol pattern is prepared (step A418).

  If the small hit flag is not a small hit (step A410; N), the stop symbol number at the time of loss is saved in the special symbol 1 stop symbol number region (step A416), and the loss stop symbol pattern is stored in the stop symbol pattern region. Save (step A417), and prepare a decorative special figure command corresponding to the stop symbol pattern (step A418). Through the above processing, a stop symbol corresponding to the result of the special figure variation display game is set.

  Thereafter, the decoration special figure command is saved in the decoration special figure command area (step A419), and an effect command setting process (step A420) is performed. This decoration special drawing command is transmitted to the effect control device 300 later. Then, the symbol data corresponding to the stop symbol number is saved in the test signal output data area (step A421), and the information in the special figure 1 big hit symbol random number storage area (for holding number 1) is cleared to "0" (step A422). Then, the information of the special figure 1 small hit symbol random number storage area (for the number of holdings 1) is cleared to “0” (step A423), and the special figure 1 stop symbol setting process is terminated.

[Special figure 2 stop symbol setting process]
Next, details of the special figure 2 stop symbol setting process (step A343) in the special figure 2 fluctuation start process described above will be described with reference to FIG. FIG. 37 is a diagram illustrating a flowchart of the special figure 2 stop symbol setting process according to the first embodiment.

  In the special figure 2 stop symbol setting process, it is first determined whether or not the big hit flag 2 is a big hit (step A431). If the big hit flag 2 is a big hit (step A431; Y), the special figure 2 big hit symbol random number storage area ( The jackpot symbol random number is loaded from the reservation number 1 (step A432). Next, a special figure 2 big hit symbol table is set (step A433), a stop symbol number corresponding to the loaded big hit symbol random number is acquired, and saved in the special figure 2 stop symbol number area (step A434). By this process, the type of special result is selected.

  Thereafter, the special symbol 2 big hit stop symbol information table is set (step A435), a stop symbol pattern corresponding to the stop symbol number is acquired, and saved in the stop symbol pattern area (step A436). The stop symbol pattern is for setting a stop symbol on the special symbol 2 symbol display unit 54 and a stop symbol on the display device 41. Next, the round number upper limit information corresponding to the stop symbol number is acquired, saved in the round number upper limit information area (step A437), the time reduction determination data corresponding to the stop symbol number is acquired, and the time reduction determination is acquired. The data area is saved (step A438), and the presentation mode transition information corresponding to the stop symbol pattern and the probability state is saved (step A439). These pieces of information are for setting the execution mode of the special gaming state and the effect mode after the special gaming state is finished. Further, in the case of the first embodiment, the big hit in the special figure 2 is a special production mode in which the production mode of the transition destination becomes the certainty change determination regardless of the big hit symbol. Then, a special decoration figure command corresponding to the stop symbol pattern is prepared (step A442).

  On the other hand, if the big hit flag 2 is not big hit (step A431; N), the stop symbol number at the time of loss is saved in the special symbol 2 stop symbol number area (step A440), and the loss stop symbol pattern is saved in the stop symbol pattern area. (Step A441), a special decoration command corresponding to the stop symbol pattern is prepared (Step A442). Through the above processing, a stop symbol corresponding to the result of the special figure variation display game is set.

  Thereafter, the decoration special figure command is saved in the decoration special figure command area (step A443), and an effect command setting process (step A444) is performed. This decoration special drawing command is transmitted to the effect control device 300 later. Then, the symbol data corresponding to the stop symbol number is saved in the test signal output data area (step A445), and the information in the special figure 2 big hit symbol random number storage area (for the number of holdings 1) is cleared to “0” (step A446). ), The special figure 2 stop symbol setting process is terminated.

  That is, the game control device 100 executes the first variation display game as the variation display game based on the detection of the game ball at the starting port 1 (starting winning port 36), and at the starting port 2 (ordinary variation winning device 37). A variation display game executing means for executing the second variation display game as the variation display game based on the detection of the game balls. In addition, the game control device 100 serves as a variable display game execution control unit that controls execution of the variable display game based on the determination result by the determination unit (game control device 100).

[Special figure information setting process]
Next, details of the special figure information setting process (steps A166, A334, A344) in the special figure hold information determination process, the special figure 1 fluctuation start process, and the special figure 2 fluctuation start process described above will be described with reference to FIG. FIG. 38 is a diagram illustrating a flowchart of special figure information setting processing according to the first embodiment.

  In the case of the first embodiment, the probability state (low / high probability, with / without time) does not affect the change distribution, and the effect mode managed by the game control device 100 affects the change distribution. In the effect mode, one effect mode is set from a plurality of effect modes according to the probability state, the presence / absence of a short time state, the progress of the special figure variation display game, and the like.

  In the special figure information setting process, first, the first half variation group selection pointer table is set (step A451), and the first half variation group selection pointer corresponding to the effect mode information is acquired (step A452).

  Next, the first-half variable group selection offset table is set (step A453), and offset data corresponding to the target special figure hold count and the stop symbol pattern is acquired (step A454).

  Next, the first-half variation group selection pointer and offset data are added (step A455), and the value obtained by the addition is saved in the variation distribution information 1 area (step A456). As a result, in the variable distribution information 1 area, the variable distribution information 1 generated based on the type of stop symbol, the number of holds, and the effect mode is saved. The fluctuation distribution information 1 is a table pointer for distributing the first half fluctuation (fluctuation mode until the start of reach), and is used to select a fluctuation group later. However, depending on the specifications of the model, since the fluctuation time is shortened only when there is a large number when the number of holdings is large, the number of holdings does not affect the distribution of the first half fluctuation as a result. A variation group includes a plurality of variation patterns. When determining a variation pattern, the variation group is first selected, and then one variation pattern is selected from the variation group. ing.

  Next, the latter half variation group selection pointer table is set (step A457), and the latter half variation group selection pointer corresponding to the effect mode information is acquired (step A458).

  Next, the second half variation group selection offset table is set (step A459), and offset data corresponding to the target special figure holding number and the stop symbol pattern is acquired (step A460).

  Next, the latter half variation group selection pointer and the offset data are added (step A461), the value obtained by the addition is saved in the variation distribution information 2 area (step A462), and the special figure information setting process is terminated. As a result, the variable distribution information 2 generated based on the stop symbol type, the number of holds, and the effect mode is saved in the variable distribution information 2 area. This fluctuation distribution information 2 is a table pointer for distributing the latter half fluctuation (reach type (including no reach)), and is used later to select a fluctuation group. However, the reach rate changes according to the number of holds only in the case of a loss (the reach rate becomes low when the number of holds is large). Does not affect.

[Variation pattern setting process]
Next, details of the above-described special figure hold information determination process, special figure 1 fluctuation start process, and fluctuation pattern setting process (steps A167, A336, A346) in the special figure 2 fluctuation start will be described with reference to FIG. FIG. 39 is a diagram illustrating a flowchart of the variation pattern setting process according to the first embodiment.

  Note that the fluctuation patterns are the first half fluctuation pattern that is a fluctuation mode from the start of the special figure fluctuation display game to the reach state, and the second half fluctuation that is a fluctuation aspect from the reach state to the end of the special figure fluctuation display game. First, the second half variation pattern is set first, and then the first half variation pattern is set.

  In the variation pattern setting process, first, a variation group address table is set (step A471), the address of the latter half variation group table corresponding to the variation distribution information 2 is acquired and prepared (step A472), and the target variation pattern is set. The fluctuation pattern random number 1 is loaded from the random number 1 storage area (for holding number 1) and prepared (step A473). In the first embodiment, the structure of the latter-half variation group table is different depending on whether it is for winning or not. Specifically, the hit use has a 1-byte size and the out-use use has a 2-byte size. The hit occurrence rate is lower than the occurrence rate of loss, and even 1 byte is sufficient. Therefore, from the viewpoint of saving the data capacity, the use is 1 byte size. Therefore, only the lower value of the 2-byte variation pattern random number 1 is used for the hit. In addition, the occurrence rate of deviation is higher than the occurrence rate of hits, and in order to make more various effects appear, the size for removal is a 2-byte size.

  Then, it is determined whether or not the result of the special figure fluctuation display game is out of place (step A474). If it is out of place (step A474; Y), a 2-byte distribution process (step A475) is performed, The process proceeds to A477, and the subsequent processes are performed. On the other hand, if it is not out of place (step A474; N), a distribution process (step A476) is performed, the process proceeds to step A477, and the subsequent processes are performed.

  Then, the address of the latter half fluctuation selection table obtained as a result of the distribution is acquired and prepared (step A477), and the fluctuation pattern random number 2 is loaded from the target fluctuation pattern random number 2 storage area (for the number of holdings 1), Prepare (Step A478). Then, a sorting process (step A479) is performed, the latter half variation number obtained as a result of the sorting is acquired and saved in the latter half variation number area (step A480). By this process, the latter half fluctuation pattern is set.

  Next, the first half variation group table is set (step A481), and a table selection pointer is calculated based on the variation distribution information 1 and the second half variation number (step A482). Then, the address of the first half variation selection table corresponding to the calculated pointer is acquired and prepared (step A483), and the variation pattern random number 3 is loaded from the target variation pattern random number 3 storage area (for the number of holdings 1). (Step A484). Thereafter, a sorting process (step A485) is performed, the first variation number obtained as a result of the sorting is acquired, saved in the first variation number area (step A486), and the variation pattern setting process is terminated. By this processing, the first half variation pattern is set, and the variation pattern of the special figure variation display game is set. That is, the game control device 100 serves as a variation pattern setting means for setting a variation pattern that is an execution mode of the game from among a plurality of variations.

[Variation start information setting process]
Next, details of the fluctuation start information setting process (steps A337 and A347) in the above-described special figure 1 fluctuation start process and special figure 2 fluctuation start process will be described with reference to FIG. FIG. 40 is a diagram illustrating a flowchart of the change start information setting process according to the first embodiment.

  In the change start information setting process, first, information on the random number storage area of the target change pattern random numbers 1 to 3 is cleared (step A491). Next, the first half variation time value table is set (step A492), and the first half variation time value corresponding to the first half variation number is acquired (step A493). Further, the latter half variation time value table is set (step A494), and the latter half variation time value corresponding to the latter half variation number is acquired (step A495).

  Then, the first half variation time value and the second half variation time value are added (step A496), and the added value is saved in the special figure game processing timer area (step A497). Thereafter, a variation command (MODE) corresponding to the first variation number is prepared (step A498), a variation command (ACTION) corresponding to the second variation number is prepared (step A499), and an effect command setting process is performed (step A500). ). Next, the special figure holding number corresponding to the variation symbol discrimination flag is updated by “−1” (step A501), and the address of the random number storage area corresponding to the variation symbol discrimination flag is set (step A502). Next, the random number storage area is shifted (step A503), the information on the free area after the shift is cleared (step A504), and the variation start information setting process is terminated.

  Through the above processing, information regarding the start of the special figure variation display game is set. That is, the game control device 100 serves as a determination unit that determines various random values stored in the start storage unit (RAM 111C). Further, the game control device 100 serves as a variation pattern determining means capable of determining a variation pattern of identification information executed in the variation display game based on the determination information of the start memory.

  Information regarding the start of the special figure variation display game is transmitted to the effect control device 300 later, and the effect control device 300 responds to the determined variation pattern based on the reception of the information regarding the start of the special figure variation display game. To set the detailed contents of the decoration special map change display game. The information related to the start of the special figure variation display game includes a decoration special figure hold number command including information related to the start memory number (holding number), a decoration special figure command including information related to the stop symbol, and a fluctuation of the special figure variation display game. A variation command including information related to the pattern and a stop information command including information related to extension of the stop time are listed, and the commands are transmitted to the effect control device 300 in this order. In particular, by transmitting the decoration special figure command before the variation command, the processing in the effect control device 300 can be efficiently advanced.

[Special figure changing process transition setting process (Special figure 1)]
Next, the details of the special-fluctuation changing process transition setting process (special figure 1) (step A310) in the special-figure normal process will be described with reference to FIG. FIG. 41 is a diagram illustrating a flowchart of the special figure changing process transition setting process (special figure 1) according to the first embodiment.

  In the special figure changing process transition setting process (special figure 1), first, “1”, which is the process number related to the special figure changing process, is set as a process number (step A511), and the special figure game process number area is processed. The number is saved (step A512).

  Then, the information in the customer waiting demo flag area is cleared (step A513), and a signal related to the fluctuation start in FIG. 1 is saved in the test signal output data area (step A514). Note that the signal related to the start of fluctuation in FIG. 1 is a signal for turning on the special symbol 1 fluctuation signal. Thereafter, the changing flag is saved in the special figure 1 fluctuation control flag area (step A515), and the initial value of the blinking control timer (the blinking cycle timer of the special figure 1 symbol display unit 53) is saved in the special figure 1 blink control timer area. (For example, 100 ms) is saved (set) (step A516), and the special figure changing process transition setting process (special figure 1) is terminated.

[Special figure changing process transition setting process (Special figure 2)]
Next, the details of the special-fluctuation changing process transition setting process (special figure 2) (step A305) in the special-figure normal process will be described with reference to FIG. FIG. 42 is a diagram illustrating a flowchart of the special figure changing process transition setting process (special figure 2) according to the first embodiment.

  In the special figure changing process transition setting process (special figure 2), first, “1”, which is the process number related to the special figure changing process, is set as a process number (step A521), and the special figure game process number area is processed. The number is saved (step A522).

  Then, the information in the customer waiting demo flag area is cleared (step A523), and a signal related to the start of fluctuation in the special figure 2 (the special symbol 2 fluctuation signal is turned on) is saved in the test signal output data area (step A524). Thereafter, the changing flag is saved in the special figure 2 fluctuation control flag area (step A525), and the initial value of the blinking control timer (timer of the blinking period of the special figure 2 symbol display unit 54) is saved in the special figure 2 blinking control timer area. Is saved (set) (step A526), and the special figure changing process transition setting process (special figure 2) is terminated.

[Special figure changing process]
Next, details of the special figure changing process (step A9) in the special figure game process described above will be described with reference to FIG. FIG. 43 is a diagram illustrating a flowchart of the special figure changing process according to the first embodiment.

  In the special figure changing process, first, the display time corresponding to the stop symbol pattern is set (step A601), and the set display time is saved in the special figure game process timer area (step A602). In the case of the first embodiment, 600 ms is set as the display time when the stop symbol pattern is an outlier symbol pattern, and 600 ms is set as the display time when the stop symbol pattern is a big hit symbol pattern. When the pattern is a small hit symbol pattern, 600 ms is set as the display time. In the case of the first embodiment, the same display time is set for the stop symbol pattern, the symbol pattern for big hit, the symbol pattern for big hit, and the symbol pattern for small hit, but different display times may be set.

  Subsequently, the special figure display process transition setting process (step A603) is performed, and the special figure display process is terminated. That is, the game control device 100 serves as stop time setting means for setting a stop time for displaying the stop result mode of the variable display game.

[Special map display process transition setting process]
Next, details of the special figure display mid-process transition setting process (step A603) in the special figure changing process described above will be described with reference to FIG. FIG. 44 is a diagram illustrating a flowchart of the special figure display mid-process transition setting process according to the first embodiment.

  In the special figure display process transition setting process, first, “2”, which is the process number related to the special figure display process, is set as a process number (step A611), and the process number is saved in the special figure game process number area ( Step A612).

  Next, a signal related to the end of the special figure 1 fluctuation is saved in the test signal output data area (step A613), and a signal related to the end of the special figure 2 fluctuation is saved in the test signal output data area (step A614). The signal related to the end of the special symbol 1 variation is a signal for turning off the special symbol 1 variation signal. The signal related to the end of the special symbol 2 variation is a signal for turning off the special symbol 2 variation signal.

  Then, the control timer initial value (for example, 256 ms) is saved in the symbol fixed number signal control timer area related to the number of times of execution of the special figure variation display game for output in the external information terminal (step A615). After that, as information for controlling the special figure 1 variable display game in the special figure 1 symbol display unit 53, a stop flag related to the variable stop in the special figure 1 symbol display unit 53 is saved in the special figure 1 fluctuation control flag region ( Step A616), as information for controlling the special figure 2 variable display game in the special figure 2 symbol display section 54, a stop flag related to the variable stop in the special figure 2 symbol display section 54 is saved in the special figure 2 fluctuation control flag area. (Step A617), and the special figure display process transition setting process is terminated.

[Special figure display processing]
Next, details of the special figure display processing (step A10) in the special figure game process described above will be described with reference to FIGS. FIG. 45 is a diagram (part 1) illustrating a flowchart of special figure display processing according to the first embodiment. FIG. 46 is a second diagram illustrating a flowchart of the special chart display process according to the first embodiment.

  In the special figure display process, first, the small hit flag set in the big hit flag 1 setting process in the special figure 1 fluctuation start process is loaded (step A701), and the information on the small hit flag area of the RWM is cleared (step A701). Step A702).

  Next, the big hit flag 1 set in the big hit flag 1 setting process in the special figure 1 variation start process and the big hit flag 2 set in the big hit flag 2 set process in the special figure 2 fluctuation start process are loaded. (Step A703), the information of the RWM big hit flag 1 area and the big hit flag 2 area is cleared (step A704). Then, it is determined whether or not the loaded big hit flag 2 is a big hit (step A705). If the big hit flag 2 is determined to be a big hit (step A705; Y), the big hit (second figure 2) of the second special figure variation display game is determined. A signal related to the start of the big hit is saved in the test signal output data area of the RWM (step A708), and a round number upper limit value table is set (step A709). The signal related to the start of the special figure 2 big hit is a signal for turning on the condition device operating signal, a signal for turning on the accessory continuous action device operating signal, and a signal for turning on the special symbol 2 hit signal. Including.

  On the other hand, if it is determined in step A705 that the big hit flag 2 is not a big hit (step A705; N) as a result of checking the big hit flag 2, it is determined whether or not the loaded big hit flag 1 is a big hit (step A706). (Step A706; Y), the test signal related to the start of the big hit (special figure 1 big hit) of the first special figure variation display game is saved in the test signal output data area of the RWM (step A707), round A number upper limit table is set (step A709). The signal related to the start of the special figure 1 big hit is a signal for turning on the condition device operating signal, a signal for turning on the accessory continuous operating device operating signal, and a signal for turning on the special symbol per signal. Including.

  Next, after setting the round number upper limit table (step A709), the round number upper limit value corresponding to the round number upper limit information (in the case of the first embodiment, “16” or “4”) is acquired, Save in the upper limit area of the round number of the RWM (step A710). Subsequently, a round LED pointer corresponding to the round number upper limit value information is acquired and saved in the round LED pointer area of the RWM (step A711).

  Next, a special decoration command corresponding to the stop symbol pattern is loaded from the special decoration command area of the RWM, prepared (step A712), and an effect command setting process (step A713) is performed. Thereafter, a probability information command related to information for setting the probability of the winning result in the normal map variation display game and the special map variation display game to be a normal probability state (low probability state) is prepared (step A714), and an effect command setting process is performed. (Step A715) is performed. Subsequently, a fanfare command corresponding to the symbol information (stop symbol number or stop symbol pattern) set in the special symbol 1 or special symbol 2 stop symbol setting process is prepared (step A716), and an effect command setting process (step A717) is performed.

  Next, the prize winning opening release information and the signal corresponding to the probability state of the winning result in the usual figure variation display game and the special figure variation display game are saved in the external information output data area of the RWM (step A718). In the case of the first embodiment, in step A718, two jackpot signals and three jackpot signals are saved as signals corresponding to the winning prize opening information and the probability state. Note that each on / off is determined by the information about the winning prize opening and the probability state. For example, the jackpot 2 signal is turned on when the jackpot is a jackpot with a lottery (the jackpot opening information is other than the jackpot opening information 1), and the jackpot without a lottery (a so-called sudden hit jackpot. When the information is the big prize opening information 1), it is turned on when it is a big hit in the short time state, and is turned off otherwise. The big hit 3 signal is turned on when a big hit with a ball is off and turned off when a big hit without a ball.

  After that, the winning prize opening information and the jackpot fanfare time (for example, 5000 ms, 4700 ms, 7700 ms, or 300 ms) corresponding to the state of the probability of being a hit result in the normal map variable display game and the special map variable display game are set. (Step A719), the set big hit fanfare time is saved in the special game processing timer area (Step A720). Then, the special game mode flag is loaded, and the loaded flag is saved in the special game mode flag save area (step A721). As a result, information on the probability state and the short time state of the special figure when the special result occurs is stored. Then, an effect mode after the end of the special game state is determined based on the information stored later.

  Then, the information on the incorrect winning prize number area of the big winning opening (special variable winning apparatus 38) corresponding to the big winning opening information is cleared (step A722), and the big winning opening corresponding to the big winning opening information is cleared. The fraud monitoring non-period monitoring period flag is saved in the big prize opening fraud monitoring period flag area (step A723). Thereafter, the fanfare / interval process transition setting process 1 (step A724) is performed, and the special figure display process is terminated.

  On the other hand, if the big hit flag 1 is not big hit in step A706 (step A706; N), it is determined whether or not the loaded small hit flag is a small hit (step A725).

  If it is determined in step A725 that the small hit flag is a small hit (step A725; Y), the high probability variation frequency update process (step A726), the production mode information check process related to the production mode setting (step A727). ) To determine whether or not the special figure has a high probability (the probability state of the special figure variation display game is a high probability state) (step A728).

  When it is determined in step A728 that the special figure high probability is not in effect (step A728; N), the special decoration command is loaded from the special decoration figure command area, prepared (step A729), and an effect command setting process (Step A730) is performed. Next, a small hitting fanfare command is prepared (step A731), an effect command setting process (step A732) is performed, the process proceeds to step A733, and the subsequent processes are performed.

  If it is determined in step A728 that the special figure has a high probability (step A728; Y), the process proceeds to step A733, and the subsequent processes are performed. As described above, in the gaming machine 10 of the first embodiment, when the probability state of the special figure variation display game is the high probability state, the big winning opening is opened by the occurrence of the small hit, but the occurrence of the small hit is generated. In order to prevent the player from being aware of this, the screen displayed on the display device 41 is not changed.

  Then, the special figure game mode flag is loaded, and the loaded flag is saved in the special figure game mode flag saving area (step A733). Thereafter, the small hitting fanfare mid-process transition setting process 1 (step A734) is performed, and the special figure display mid-process is terminated.

  On the other hand, if it is determined in step A725 that the small hit flag is not a small hit (step A725; N), the high probability variation frequency update process (step A735), the production mode information check process related to the production mode setting (step A735). A736) is performed, the remaining switching preparation rotation speed corresponding to the effect mode number is set (step A737), and it is determined whether or not the remaining production rotation speed matches the remaining switching preparation rotation speed (step A738). Note that the remaining rotation speed for switching preparation is a different value (rotation speed: for example, mode A is 4 times, mode B is 3 times, mode C is 8 times, etc.) in all the effect modes of the plurality of effect modes. It may be the same value (number of rotations) in any one of the plurality of effect modes, or the same value (number of rotations) in all the effect modes of the plurality of effect modes. ).

  If it is determined in step A738 that the remaining rotation speed for production and the remaining rotation speed for switching preparation do not match (step A738; N), special figure normal process transition setting process 1 (step A741) is performed to display the special figure. End the middle process.

  On the other hand, if it is determined in step A738 that the remaining production rotation speed matches the remaining switching preparation rotation speed (step A738; Y), a production mode switching preparation command is prepared (step A739), and production command setting is performed. After performing the process (step A740), the special figure normal process transition setting process 1 (step A741) is performed, and the special figure display process is terminated. The production mode switching preparation command is a command for preventing the pre-reading production from being performed several rotations before the production mode is switched. It is possible to prevent contradiction from occurring.

[High probability change count update processing]
Next, details of the high probability variation number update process (steps A726 and A735) in the special chart display process will be described with reference to FIG. FIG. 47 is a diagram illustrating a flowchart of high probability variation frequency update processing according to the first embodiment.

  In the high probability variation frequency update process, first, it is determined whether or not the special figure high probability is in effect (step A751), and if the special figure high probability is not significant (step A751; N), the high probability variation frequency update processing is performed. Exit.

  When the special figure high probability is in progress (step A751; Y), the high probability fluctuation number for managing the number of executions of the special figure fluctuation display game to be in the high probability state is updated by “−1” (step A752). It is determined whether or not the probability variation number is “0” (step A753).

  If the high probability variation number is not “0” (step A753; N), the high probability variation number update process is terminated. When the number of high-probability fluctuations is “0” (step A753; Y), the information in the high-probability notification flag area is cleared (step A754), and a signal related to high-probability end is saved in the external information output data area ( Step A755). The signal relating to the high probability end is a signal for turning off the two jackpot signals.

  Then, a signal relating to the end of the high probability & short time (high probability & no time short or high probability & short time) is saved in the test signal output data area (step A756). The signals related to the end of the high probability & short time are the signals that turn off the special symbol 1 high probability state signal, the signals that turn off the special symbol 2 high probability state signal, and the special symbol 1 variable time shortening state signal. , A signal for turning off the special symbol 2 variation time reduction state signal, and a signal for turning off the normal symbol 1 high probability state signal. In addition, even during the special figure high probability, only the probability state changes in the normal figure, so the normal symbol 1 variation time shortening state signal and the normal electric accessory 1 open extension state signal are always off.

Then, the timeless number is saved in the game state display number area (step A757), and the ordinary low probability flag is saved in the ordinary game mode flag area (step A758).
Then, the special figure low probability & no short time flag is saved in the special figure game mode flag area (step A759), and a signal relating to the left-handed instruction is saved in the test signal output data area (step A760). The signal related to the left hand instruction is a signal for turning off the firing position designation signal 1. Then, to turn off the right-handed display LED, the number in the left-handed state is saved in the game state display number 2 area (step A761), and the high-probability variation number updating process is terminated.

[Direction mode information check processing]
Next, details of the effect mode information check process (steps A727 and A736) in the special figure display process will be described with reference to FIG. FIG. 48 is a diagram illustrating a flowchart of effect mode information check processing according to the first embodiment.

  In the production mode information check process, first, it is determined whether or not the next mode transition information is a no-update code (step A771). If the next mode transition information is a no-update code (step A771; Y), The effect mode information check process is terminated. In this case, the production mode is not changed according to the number of executed special figure variation display games, and for example, the production mode that continues until the next big hit in the high probability state is selected. It is.

  If the next mode transition information is not a non-updated code (step A771; N), the effect remaining rotation number that is the number of executions of the special figure variation display game until the change of the effect mode is updated by “−1” (step A772). ), It is determined whether or not the remaining rotational speed of the effect is “0” (step A773). The process of step A772 serves as a counting means for counting the number of executions of the first special figure fluctuation display game and the second special figure fluctuation display game.

  If the remaining effect rotation speed is not “0” (step A773; N), the effect mode information check process is terminated. When the remaining effect rotation speed is “0” (step A773; Y), that is, when changing the effect mode from the next special figure variation display game, an effect mode information address table is set (step A774), The address of the table corresponding to the next mode transition information is acquired (step A775).

  The effect mode number of the effect mode to be transferred is acquired and saved in the effect mode number area (step A776), and the remaining effect rotation speed of the effect mode to be transferred is acquired and saved in the effect remaining speed area (step A777). The effect mode to be transferred (the effect mode of the transfer destination) can be known from the next mode change information already saved before step A776. The next mode transition information relating to the next rendering mode of the transitioning rendering mode is acquired and saved in the next mode transition information area (step A778). In addition, the process of step A776 performs effect mode execution control means for performing execution control of any effect mode (game mode) among a plurality of effect modes (game mode) corresponding to the counting result by the counting means (step A772). (Game mode execution control means).

  A probability information command corresponding to the effect mode number acquired in step A776 is prepared (step A779), and it is determined whether or not the prepared probability information command matches the value of the transmission command area at the time of power failure recovery (step A780). When the prepared probability information command matches the value of the transmission command area at the time of power failure recovery, that is, when the probability state does not change (step A780; Y), the rendering mode is transmitted without transmitting the command to the rendering control device 300. The information check process ends. When the prepared probability information command does not match the value of the transmission command area at the time of power failure recovery (step A780; N), the prepared probability information command is saved in the transmission command area at the time of power failure recovery (step A781), and the production command is set. Processing (step A782) is performed.

  Then, an effect rotation speed command corresponding to the effect remaining rotation speed acquired in step A777 is prepared (step A783), and an effect command setting process (step A784) is performed. Then, a high probability variation number command corresponding to the high probability variation number is prepared (step A785), an effect command setting process (step A786) is performed, and it is determined whether or not the new effect mode is a left-handed mode. (Step A787).

  If the new effect mode is not a left-handed mode (step A787; N), the effect mode information check process is terminated. If the new effect mode is a left-handed mode (step A787; Y), a left-handed instruction notification command is prepared (step A788), an effect command setting process (step A789) is performed, and effect mode information check is performed. End the process.

[Fanfare / interval process transition setting process 1]
Next, the details of the fanfare / interval process transition setting process 1 (step A724) in the special figure display process described above will be described with reference to FIG. FIG. 49 is a diagram illustrating a flowchart of the process for setting the transition to the fanfare / interval process according to the first embodiment.

  In the fanfare / interval process transition setting process 1, first, “3”, which is a process number related to the fanfare / interval process, is set as a process number (step A791), and the process number is saved in the special game process number area. (Step A792).

  Next, a signal relating to the start of the big hit (special game state) is saved in the external information output data area (step A793). The signals relating to the start of the big hit include, for example, a signal for turning on one big hit signal (output with a big hit + small hit) and a signal for turning on four signals (output with a big hit).

  Next, a signal relating to the end of high probability & short time is saved in the test signal output data area (step A794). Signals related to the end of high probability & short time are, for example, a signal that turns off the special symbol 1 high probability state signal, a signal that turns off the special symbol 2 high probability state signal, and a signal that turns off the special symbol 1 high probability state signal. , A signal for turning off the special symbol 2 variation time reduction state signal, and a signal for turning off the normal symbol 1 high probability state signal.

  Thereafter, information on the number of rounds area for managing the number of rounds executed in the special game state is cleared (step A795), and a number without time is saved in the game state display number area (step A796). Save the ordinary low probability flag in the area (step A797).

  Then, the information in the variation symbol determination flag area is cleared (step A798), and the information in the high probability notification flag area is cleared in order to turn off the gaming state display LED related to the high probability state display (step A799). A special figure low probability & no short time flag is saved in the figure game mode flag area (step A800). Next, a probability information command (low probability) is saved in the transmission command area at the time of power failure recovery to save the command output to the production control device 300 at the time of power failure recovery (step A801), and the special figure change that can be executed in a high probability state The information of the high probability variation frequency area for managing the number of times of the display game is cleared (step A802). As a result, the high-probability state and the short-time state are terminated, and the normal probability state and the normal state are obtained.

  Thereafter, the number of the effect mode 1 is saved in the effect mode number area (step A803), and the game control apparatus 100 manages the effect mode, so the information on the remaining effect rotation speed area is cleared (step A804). Then, the non-update code is saved in the next mode transition information area (step A805). Then, a signal related to the right-handed instruction (launching position designation signal 1 is turned on) is saved in the test signal output data area (step A806), and the right-handed display LED is turned on so The number in the state is saved (step A807), and the fanfare / interval process transition setting process 1 ends. As a result, the information on the effect mode is once cleared with the occurrence of the special game state.

[Small hit fanfare mid-process transition setting process 1]
Next, the details of the small hit fanfare mid-process transition setting process 1 (step A734) in the above-described special figure display mid-process will be described with reference to FIG. FIG. 50 is a diagram illustrating a flowchart of the process transition setting process 1 during small hitting fanfare of the first embodiment.

  In the small hitting fanfare process transition setting process 1, first, “7”, which is a process number related to the small hitting fanfare process, is set as a process number (step A811), and the process number is saved in the special figure game process number area. (Step A812). Then, the small hit fanfare time (for example, 300 ms) is saved in the special game processing timer area (step A813), and a signal relating to the start of the small hit is saved in the external information output data area (step A814). The signal relating to the start of the small hit is, for example, a signal that turns on one big hit signal (outputs with a big hit + small hit).

  Then, a signal relating to the start of the small hit is saved in the test signal output data area (step A815). The signal regarding the start of the small hit is, for example, a signal for turning on the special symbol one small hit signal.

  Then, the information on the illegal winning opening illegal prize number area is cleared (step A816), and the illegal winning period illegal monitoring period flag area is saved in the illegal winning opening illegal monitoring period flag area (step A817). Then, the signal related to the right-handed instruction is saved in the test signal output data area (step A818). The signal relating to the right-handed instruction is, for example, a signal for turning on the launch position designation signal 1.

  Then, in order to turn on the right-handed display LED, the right-handed state number is saved in the game state display number 2 area (step A819), and the small hit fanfare mid-process transition setting process 1 is completed.

[Fanfare / In-interval processing]
Next, the details of the fanfare / interval process (step A11) in the above-described special figure game process will be described with reference to FIG. FIG. 51 is a flowchart of the fanfare / interval processing according to the first embodiment.

  In the fanfare / interval processing, first, the number of rounds in the special gaming state is updated by “+1” (step A901), a round command corresponding to the number of rounds in the special gaming state is prepared (step A902), and the effect command setting process (Step A903) is performed.

  After that, a special winning opening operation determination table is set (step A904), an opening switching determination value corresponding to the large winning opening information is acquired (step A905), and the number of rounds in the special gaming state is acquired. It is determined whether or not the value is larger than the value (step A906).

  When the number of rounds is larger than the opening switching determination value (step A906; Y), the opening time of the large winning opening for short opening (in the case of the first embodiment, 0.2 s) is set in the special game processing timer area. After saving (step A907), a special winning opening opening process transition setting process (step A909) is performed to release the special winning opening, and the fanfare / interval processing is terminated.

  If the number of rounds is not larger than the opening switching determination value (step A906; N), the opening time of the large winning opening for long opening (29s in the case of the first embodiment) is set as the special-purpose game processing timer area. (Step A908), a special winning opening opening process transition setting process (Step A909) is performed in order to open the special winning opening, and the fanfare / interval processing is terminated.

  Here, in the first embodiment, (1) 4R, special winning opening release information 1 (all short opening), (2) 16R, special winning opening release information 2 (all long opening), ( 3) 16R, special prize opening information 3 (1-4R is long open, 5-16R is short open), (4) 4R, special prize opening information 4 (all long open), (5) 16R, big prize Mouth open information 5 (all long open), (6) 16R, big prize opening information 6 (1-8R is long open, 9-16R is short open), (7) 16R, big prize opening information 7 (1 -4R is set to long open, and 5-16R is set to short open).

  Therefore, in the big prize opening operation determination table, the big prize opening information 1 data and the opening switching determination value “0”, the big winning opening information 2 data and the opening switching determination value “16” are the big winning opening. The opening information 3 data and the opening switching determination value “4” are the big winning opening opening information 4 data and the opening switching determination value “4”, and the big winning opening opening information 5 data and the opening switching determination value “16” are. The special winning opening opening information 6 data and the opening switching determination value “8” are stored in association with the large winning opening opening information 7 data and the opening switching determination value “4” in association with each other. Then, an opening operation is performed so that long opening is performed while the number of rounds is equal to or less than the opening switching determination value, and short opening is performed when the number of rounds exceeds the opening switching determination value.

[Large winning opening open process transition setting process]
Next, the details of the process for setting the transition to the large winning opening opening process (step A909) in the above-described fanfare / interval process will be described with reference to FIG. FIG. 52 is a diagram illustrating a flowchart of the process transition setting process during the special prize opening opening according to the first embodiment.

  In the process for setting a process for opening a special prize opening, first, “4”, which is a process number related to the process for opening a special prize opening, is set as a process number (step A911), and the process number is saved in the special game process number area. (Step A912). Thereafter, a signal relating to the opening of the special winning opening (special variable winning device 38) is saved in the test signal output data area (step A913). The signal related to the start of opening of the big prize opening is, for example, a signal for turning on the special electric accessory 1 operating signal.

  Next, the information on the number-of-award winning number count area for storing the number of winnings to the winning a prize opening is cleared (step A914). Then, the ON data of the special winning a prize opening (special variable prize-winning device 38) is saved in the special winning opening solenoid output data area (step A915), and the special prize opening opening process transition setting process is terminated.

[Processing during the grand prize opening]
Next, the details of the special winning opening opening process (step A12) in the special figure game process described above will be described with reference to FIG. FIG. 53 is a view illustrating a flowchart of the special winning opening opening process according to the first embodiment.

  In the process of opening the special winning opening, first, the current round number in the special game state being executed is compared with the round number upper limit value in the RWM round number upper limit area to determine whether the current round is the final round. Is determined (step A1001).

  If it is the final round (step A1001; Y), the final remaining ball processing time (for example, 1.9s) is saved in the special-purpose game processing timer area (step A1008), and an ending command is prepared (step A1009), the process proceeds to step A1010, and the subsequent processes are performed.

  If it is not the final round (step A1001; N), a big winning opening operation determination table is set (step A1002), an opening switching determination value corresponding to the big winning opening opening information is acquired (step A1003), and the number of rounds is It is determined whether or not the open switching determination value is exceeded (A1004).

  If the number of rounds exceeds the open switching determination value (step A1004; Y), the remaining ball processing time for short closing (for example, 1.4 s) is saved in the special game processing timer area (step A1005). Then, an interval command is prepared (step A1007), the process proceeds to step A1010, and the subsequent processes are performed.

  If the number of rounds does not exceed the open switching determination value (step A1004; N), the remaining ball processing time for long closing (for example, 1.9 s) is saved in the special game processing timer area (step A1006). Then, an interval command is prepared (step A1007), the process proceeds to step A1010, and the subsequent processes are performed.

Thereafter, an effect command setting process (step A1010) is performed, a special winning opening remaining ball process transition setting process (step A1011) is performed, and the special winning opening open process is terminated.
[Large winning ball remaining ball processing transition setting processing]
Next, details of the big winning opening remaining ball processing shift setting process (step A1011) in the above-described big winning opening open process will be described with reference to FIG. FIG. 54 is a diagram illustrating a flowchart of a special winning opening remaining ball process transition setting process according to the first embodiment.

  In the winning prize remaining ball processing transition setting process, first, “5”, which is the processing number related to the winning ball remaining ball processing, is set as the processing number (step A1021), and the processing number is saved in the special figure game processing number area. (Step A1022). Then, off data of the special winning a prize opening (special variable prize-winning device 38) is saved in the special winning opening solenoid output data area (step A1023), and the special winning opening remaining ball processing transition setting process is terminated.

[Large winning ball remaining ball processing]
Next, details of the big winning opening remaining ball process (step A13) in the above-described special figure game process will be described with reference to FIG. FIG. 55 is a diagram illustrating a flowchart of the extra winning opening remaining ball process according to the first embodiment.

  In the winning ball remaining ball processing, first, whether the current round is the final round by comparing the current round number in the special game state being executed and the round number upper limit value in the round number upper limit area of the RWM. Is determined (step A1101).

  In the case of the final round (step A1101; Y), a flag is loaded from the special figure game mode flag save area (step A1111), and the ending time corresponding to the loaded flag, the special winning opening release information, and the stop symbol pattern ( For example, 1.9 s) is set (step A1112). Then, the ending time is saved in the special figure game process timer area (step A1113), the big hit end process transition setting process (step A1114) is performed, and the big winning opening remaining ball process is ended.

  If it is not the final round (step A1101; N), a special winning opening operation determination table is set (step A1102), and an open switching determination value corresponding to the special winning opening information is acquired (step A1103). Then, a normal interval time (for example, 0.1 s) is set (step A1104), it is determined whether the number of rounds is larger than the open switching determination value (step A1105), and the number of rounds is larger than the open switching determination value. In the case (step A1105; Y), the process proceeds to step A1109 and the subsequent processes are performed.

  When the number of rounds is not larger than the opening switching value (step A1105; N), it is determined whether or not the big winning opening information is a rank-down effect type value (step A1106), and the big winning opening information is If it is not a rank-down effect system value (step A1106; N), the process proceeds to step A1109 and the subsequent processes are performed.

  When the big prize opening information is a rank-down effect type value (step A1106; Y), it is determined whether or not the number of rounds is a special effect round value (for example, 2R, 4R, 8R) ( If the number of rounds is not the value of the special effect round (step A1107) (step A1107; N), the process proceeds to step A1109 and the subsequent processes are performed.

  When the number of rounds is the value of the special effect round (step A1107; Y), an interval time for rank-down effect (for example, 3.6 s) is set (step A1108), and the process proceeds to step A1109. The subsequent processing is performed.

  Then, the interval time is saved in the special game process timer area (step A1109), the fanfare / interval process transition setting process 2 (step A1110) is performed, and the big winning opening remaining ball process is terminated.

[Fanfare / interval process transition setting process 2]
Next, the details of the fanfare / interval process transition setting process 2 (step A1110) in the above-described winning prize remaining ball process will be described with reference to FIG. FIG. 56 is a diagram illustrating a flowchart of the fanfare / interval process transition setting process 2 according to the first embodiment.

  In the fanfare / interval process transition setting process 2, first, “3”, which is the process number related to the fanfare / interval process, is set as a process number (step A1121), and the process number is saved in the special game process number area. (Step A1122). Then, a signal relating to the end of opening of the special winning opening (special variable winning device 38) is saved in the test signal output data area (step A1123). The signal related to the end of the special winning opening is a signal for turning off the special electric accessory 1 operating signal, for example.

Then, the fanfare / interval process transition setting process 2 ends.
[Big jackpot end process transition setting process]
Next, details of the jackpot end process transition setting process (step A1114) in the above-described winning prize remaining ball process will be described with reference to FIG. FIG. 57 is a diagram illustrating a flowchart of the jackpot end process transition setting process according to the first embodiment.

  In the jackpot end process transition setting process, first, “6”, which is a process number related to the jackpot end process, is set as a process number (step A1131), and the process number is saved in the special figure game process number area (step A1132).

  Then, a signal relating to the end of opening of the special winning opening (special variable winning device 38) is saved in the test signal output data area (step A1133). The signal related to the end of the special winning opening is a signal for turning off the special electric accessory 1 operating signal, for example.

  Next, the information on the number-of-winner count area for storing the number of wins to the prize-winning mouth is cleared (step A1134), and the information on the number-of-rounds area for storing the number of rounds in the special gaming state is cleared (step A1135). . Then, the information of the round number upper limit area for storing the upper limit value of the round number in the special gaming state is cleared (step A1136), and the information of the round number upper limit information area for storing the flag for determining the upper limit value of the round number is stored. Clear (step A1137). Then, the information of the big winning opening release information area storing the big winning opening release information determination flag is cleared (step A1138), and the big hit end transition setting process is ended.

[Big hits end processing]
Next, details of the jackpot end process (step A14) in the above-described special figure game process will be described with reference to FIG. FIG. 58 is a diagram illustrating a flowchart of the big hit end process according to the first embodiment.

  In this jackpot end process, first, it is determined whether or not the time reduction determination data is time-saving operation data (step A1201). If it is not the short time operation data (step A1201; N), the big hit end setting process 1 (step A1202) is performed, and if it is the short time operation data (step A1201; Y), the big hit end setting process 2 (step A1203) is performed. .

  Then, the production mode information address table is set (step A1204), and the address of the table corresponding to the production mode transition information set at the start of variation (when the stop symbol is set) is acquired (step A1205).

  Next, as processing for saving the information necessary for managing the production mode in the game control device 100, first, the production mode number of the production mode set after the end of the special game state is acquired and saved in the production mode number area. (Step A1206). Further, the effect remaining speed of the effect mode set after the end of the special gaming state is acquired, saved in the effect remaining speed region (step A1207), and the next mode of the effect mode set after the end of the special game state. Transition information is acquired and saved in the next mode transition information area (step A1208).

  Thereafter, a probability information command corresponding to the effect mode number is prepared (step A1209), the command is saved in the transmission command area at the time of power failure recovery (step A1210), and an effect command setting process (step A1211) is performed.

  As the probability information command, there are a plurality of commands that include information on the production mode in either “high probability / with time reduction” or “high probability / without time reduction”. In the case of the first embodiment, since the probabilistic state (so-called ST state) is always obtained when the big hit ends, the probability information commands include “high probability / short time / direction mode A”, “high probability / short time / direction” “Mode B”, “High probability / short time / direction mode C”, “High probability / no time / direction mode A” are not used in this process. ”,“ Low probability / no time reduction / production mode B ”, and“ low probability / no time reduction / production mode C ”.

Next, an effect rotation speed command corresponding to the remaining effect rotation speed is prepared (step A1212), and an effect command setting process (step A1213) is performed.
Next, a high probability variation number command corresponding to the high probability variation number is prepared (step A1214), an effect command setting process (step A1215) is performed, and it is determined whether or not a short-time state occurs after the end of the big hit (step A1214). A1216).

If a short-time state occurs after the big hit (step A1216; Y), the special figure normal process transition setting process 2 (step A1219) is performed, and the big hit end process ends.
Further, when the time-short state does not occur after the big hit (Step A1216; N), a left-handed instruction notification command is prepared (Step A1217), and after performing the effect command setting process (Step A1218), the special figure normal process shifts. Setting process 2 (step A1219) is performed, and the jackpot end process is terminated.

[Big jackpot end setting 1]
Next, details of the jackpot end setting process 1 (step A1202) in the jackpot end process described above will be described with reference to FIG. FIG. 59 is a diagram illustrating a flowchart of the jackpot end setting process 1 according to the first embodiment.

  In the jackpot end setting process 1, first, a signal related to the absence of a time-short state is saved in the external information output data area (step A1221). The signal related to the absence of the short-time state is, for example, a signal for turning off two jackpot signals.

  Next, a signal related to the start of the high probability state and the absence of the short time state is saved in the test signal output data area (step A1222). The signals relating to the start of the high probability state and the absence of the short time state are, for example, a signal for turning on the special symbol 1 high probability state signal, a signal for turning on the special symbol 2 high probability state signal, and a special symbol 1 variation time. It includes a signal for turning off the shortened state signal, a signal for turning off the special symbol 2 variation time shortened state signal, and a signal for turning off the normal symbol 1 high probability state signal.

  Next, a number without a short time state is saved in the game state display number area (step A1223), a common low probability flag is saved in the normal game mode flag area (step A1224), and the special game mode flag area is saved. The special figure high probability & no short time flag is saved (step A1225). Thereafter, an initial value (for example, 100 times) is saved in the high probability variation count area (step A1226), and a signal related to the left-handed instruction is saved in the test signal output data area (step A1227). The signal relating to the left-handed instruction is, for example, a signal for turning off the launch position designation signal 1.

Next, in order to turn off the right-handed display LED, the number in the left-handed state is saved in the game state display number 2 area (step A1228), and the big hit end setting process 1 is finished.
[Big hit end setting process 2]
Next, details of the jackpot end setting process 2 (step A1203) in the above jackpot end process will be described with reference to FIG. FIG. 60 is a diagram illustrating a flowchart of the jackpot end setting process 2 according to the first embodiment.

  In the jackpot end setting process 2, first, a signal related to the start of the time-saving state is saved in the external information output data area (step A1231). The signal relating to the start of the short-time state is, for example, a signal for turning on two jackpot signals. Since the signal related to the start of the short-time state is output from the big hit, it is saved in the external information output data area in a continuous manner.

  Next, a signal related to the start of the high probability state and the short time state is saved in the test signal output data area (step A1232). The signals relating to the start of the high probability state and the short time state are, for example, a signal for turning on the special symbol 1 high probability state signal, a signal for turning on the special symbol 2 high probability state signal, and a special symbol 1 variable time shortening state signal. , A signal for turning on the special symbol 2 variation time shortening state signal, and a signal for turning on the normal symbol 1 high probability state signal.

  Next, the number with the short time state is saved in the game state display number area (step A1233), the common figure high probability flag is saved in the ordinary figure game mode flag area (step A1234), and the special figure game mode flag area is saved. The special figure high probability & short time flag is saved (step A1235). Thereafter, an initial value (for example, 100 times) is saved in the high probability variation frequency area (step A1236), and the jackpot end setting process 2 is ended. In the case of the first embodiment, the right-handed mode is set during the time-shortening state, but the right-handed mode is set from the middle-hit, so the setting for the right-handed end setting process 2 is not performed.

[Special figure transition setting process 2]
Next, details of the special figure normal process transition setting process 2 (step A1219) in the above jackpot end process will be described with reference to FIG. FIG. 61 is a diagram illustrating a flowchart of the special figure normal process transition setting process 2 according to the first embodiment.

  In the special figure normal process transition setting process 2, first, “0”, which is the process number related to the special figure normal process, is set as the process number (step A1241), and the process number is saved in the special figure game process number area (step S1241). A1242).

  Thereafter, a signal relating to the end of the jackpot is saved in the external information output data area (step A1243). The signals relating to the end of the jackpot include, for example, a signal for turning off the jackpot 1 signal, a signal for turning off the jackpot 3 signal, and a signal for turning off the jackpot 4 signal.

  Next, a signal relating to the end of jackpot is saved in the test signal output data area (step A1244). The signal regarding the end of the jackpot is a signal for turning off the condition device operating signal, a signal for turning off the continuous action device operating signal, a signal for turning off the special symbol 1 signal, and a special symbol 2 signal. Includes a signal that turns off the signal.

  Subsequently, the information in the time reduction determination flag area is cleared (step A1245), the information in the pointer area of the round LED indicating the number of rounds of the big hit is cleared (step A1246), and the information in the effect mode transition information area is cleared. (Step A1247). Then, the information of the special figure game mode flag saving area is cleared (step A1248), the fraud monitoring period flag is saved in the special prize opening fraud monitoring period flag area (step A1249), and the special figure normal process transition setting process 2 is performed. Exit.

[Small fanfare during processing]
Next, details of the small hitting fanfare process (step A15) in the special figure game process described above will be described with reference to FIG. FIG. 62 is a diagram illustrating a flowchart of small hitting fanfare processing according to the first embodiment.

In the small hitting fanfare process, the small hitting medium process transition setting process (step A1301) is performed, and the small hitting fanfare process is terminated.
[Small hit middle processing transition setting processing]
Next, details of the small hitting process transition setting process (step A1301) in the small hitting fanfare medium process will be described with reference to FIG. FIG. 63 is a diagram illustrating a flowchart of the small hitting process transition setting process according to the first embodiment.

  In the small hit / medium process transition setting process, first, “8”, which is the process number related to the small hit / medium process, is set as the process number (step A1311), and the process number is saved in the special figure game process number area (step A1312). ).

  Then, a small hit release time (for example, 0.2 s) is set in the special figure game processing timer area (step A1313), and a signal related to the start of the small hit operation is saved in the test signal output data area (step A1314). The signal relating to the start of the small hitting operation is, for example, a signal for turning on the special electric accessory 1 operating signal.

  Then, on data of the special winning a prize opening (special variable prize-winning device 38) is saved in the special winning opening solenoid output data area (step A1315), and information of the special winning prize count number area for storing the number of winning prizes to the special winning opening is stored. Clear (step A1316).

Then, the small hitting operation initial value (for example, “0”) is saved in the small hitting / measuring control pointer area (step A1317), and the small hitting / medium processing transition setting process is terminated.
[Processing during small hits]
Next, details of the middle hit process (step A16) in the above-described special figure game process will be described with reference to FIG. FIG. 64 is a diagram illustrating a flowchart of the small hitting process according to the first embodiment.

  In the small hit / medium process, first, the small hit / medium control pointer is loaded from the small hit / medium control pointer area (step A1401), and the value of the loaded small hit / medium control pointer is the small hit operation end value (for example, “6”). It is determined whether or not this is the case (step A1402).

  If the value of the loaded small hitting control pointer is not equal to or larger than the small hitting operation end value (step A1402; N), the value of the small hitting control pointer in the small hitting control pointer area is updated by “+1” (step A1403). ), A small hitting action transition setting process (step A1404) is performed, and the small hitting medium process is terminated. When the value of the loaded small hitting control pointer is equal to or larger than the small hit action end value (step A1402; Y), the flag is loaded from the special-purpose game mode flag save area (step A1405). It is determined whether or not the figure is in a high probability (step A1406). Note that the determination in step A1406 is based on the probability state and not the short-time state.

  When the loaded flag is in the special figure high probability (step A1406; Y), the process proceeds to step A1409 and the subsequent processes are performed. If the loaded flag is not in the special figure high probability (step A1406; N), a command for the small hit end screen is prepared (step A1407), and an effect command setting process (step A1408) is performed. Then, the small hit remaining ball processing transition setting processing (step 1409) is performed, and the small hit middle processing is terminated.

[Small hit operation transition setting process]
Next, details of the small hit motion transition setting process (step A1404) in the above-described small hit middle process will be described with reference to FIG. FIG. 65 is a diagram illustrating a flowchart of the small hitting operation transition setting process according to the first embodiment.

  In the small hit operation transition setting process, first, the value of the small hit medium control pointer loaded in step A1401 is determined (step A1411). When the value of the small hit / medium control pointer loaded in step A1401 is “0”, “2”, or “4” (step A1411; pointer = 0, 2, 4), the value of the small hit / medium control pointer is set. The corresponding wait time (1500 ms) is saved in the special figure game processing timer area (step A1412). Then, the off data of the big prize opening (special variable prize-winning device 38) is saved in the big prize opening solenoid output data area (step A1413), and the small hitting action transition setting process is ended.

  When the value of the small hitting control pointer loaded in step A1401 is “1”, “3”, or “5” (step A1411; pointer = 1, 3, 5), the value of the small hitting control pointer is set to the value. The corresponding special winning opening time (200 ms) is saved in the special game process timer area (step A1414). Then, the ON data of the special winning a prize opening (special variable prize-winning device 38) is saved in the special winning opening solenoid output data area (step A1415), and the small hitting action transition setting process is terminated.

  Here, the small hitting operation will be described with reference to FIG. FIG. 66 is a diagram illustrating a timing chart of the small hit operation according to the first embodiment. In the figure, the numbers in the squares indicate the values of the control pointers.

  The small hitting operation includes a small hitting fanfare time (300 ms), a subsequent large winning opening opening time (200 ms), a subsequent waiting time (1500 ms), a subsequent large winning opening opening time (200 ms), and a subsequent weight. A time (1500 ms), a subsequent winning opening opening time (200 ms), a subsequent wait time (1500 ms), a subsequent winning opening opening time (200 ms), a remaining ball processing time (1900 ms), It is a series of operations for a total of 7600 ms, which consists of a small hitting ending time (100 ms).

  In the case of the small hitting operation, the control pointer value becomes “0” after the first big winning opening opening time elapses, and the control pointer value goes through the respective processes corresponding to “0” to “5”. The value of the control pointer is “6”. In this way, in the case of the small hitting operation, the small hitting remaining ball processing is performed after the four opening operations of the special variable winning device 38. In the small hitting operation, the small hitting ending time is set after the remaining ball processing time, so that an apparent ending time is obtained by adding the remaining ball processing time 1900 ms to the control small hitting ending time 100 ms.

  Note that during the small hitting fanfare time, the wait time, the remaining ball processing time, and the small hitting ending time, the special variable winning device 38 is closed by the off control of the big winning port solenoid 38b. Further, during the special winning opening opening time, the special variable winning apparatus 38 is opened by the on-control of the special winning opening solenoid 38b.

[Small hit remaining ball processing transition setting processing]
Next, details of the small hit remaining sphere process shift setting process (step A1409) in the above-described small hit middle process will be described with reference to FIG. FIG. 67 is a diagram illustrating a flowchart of the small hit remaining sphere process transition setting process according to the first embodiment.

  In the small hit remaining ball process transition setting process, first, “9”, which is the process number related to the small hit remaining ball process, is set as the process number (step A1421), and the process number is saved in the special figure game process number area ( Step A1422).

  Then, the small hit remaining ball processing time (for example, 1.9 s) is saved in the special figure game processing timer area (step A1423), and the large winning opening (special variable winning apparatus 38) is turned off in the large winning opening solenoid output data area. The data is saved (step A1424), and the small hit remaining ball process transition setting process is terminated.

[Small ball remaining treatment]
Next, details of the small hit remaining ball process (step A17) in the special figure game process described above will be described with reference to FIG. FIG. 68 is a diagram illustrating a flowchart of the small hit remaining sphere process according to the first embodiment.

In the small hit remaining ball process, the small hit end process shift setting process (step A1501) is performed, and the small hit remaining ball process is terminated.
[Small hit end process transition setting process]
Next, details of the small hit end process transition setting process (step A1501) in the small hit remaining ball process will be described with reference to FIG. FIG. 69 is a diagram illustrating a flowchart of the small hit end process transition setting process according to the first embodiment.

  In the small hit end process transition setting process, first, “10”, which is the process number related to the small hit end process, is set as the process number (step A1511), and the process number is saved in the special figure game process number area (step A1512). ).

  Then, the small hitting ending time (for example, 0.1 s) is saved in the special figure game processing timer area (step A1513), and a signal relating to the end of the small hitting operation is saved in the test signal output data area (step A1514). The signal relating to the end of the small hitting operation is, for example, a signal for turning off the special electric accessory 1 operating signal.

  Then, the information of the big winning mouth count number area for storing the number of winning prizes to the big winning mouth is cleared (step A1515), the information of the small hitting control pointer area is cleared to zero (step A1516), and the small hit end transition setting process is performed. Exit.

[Small hit end processing]
Next, details of the small hit end process (step A18) in the above-described special figure game process will be described with reference to FIG. FIG. 70 is a diagram illustrating a flowchart of the small hit end process according to the first embodiment.

  In the small hit end process, first, a flag relating to the probability state is loaded from the special figure game mode flag saving area (step A1601), and it is determined whether or not the flag loaded in step A1601 is in the special figure high probability (step A1601). A1602). If the flag loaded in step A1601 has a special figure high probability (step A1602; Y), the process proceeds to step A1619 and the subsequent processes are performed.

  When the flag loaded in step A1601 is not in the special figure high probability (step A1602; N), an effect mode information address table is set (step A1603), and the effect set at the start of variation (when the stop symbol is set). The address of the table corresponding to the mode transition information is acquired (step A1604).

  Then, the effect mode number is acquired and saved in the effect mode number area (step A1605), the effect remaining rotation speed is acquired and saved in the effect remaining rotation speed area (step A1606), and the next mode transition information is acquired. Save in the next mode transition information area (step A1607).

  Then, a probability information command corresponding to the effect mode number acquired in step A1606 is prepared (step A1608), and it is determined whether or not the prepared probability information command matches the value in the power failure recovery transmission command area (step A1609). .

  If the prepared probability information command matches the value in the power failure recovery transmission command area (step A1609; Y), the process proceeds to step A1619 and the subsequent processes are performed. If the prepared probability information command does not match the value of the power failure recovery transmission command area (step A1609; N), the probability information command is saved in the power failure recovery transmission command area (step A1610), and an effect command setting process (step A1611) is performed.

  Then, an effect rotation speed command corresponding to the effect remaining rotation speed acquired in step A1606 is prepared (step A1612), and an effect command setting process (step A1613) is performed. Also, a high probability variation number command corresponding to the high probability variation number is prepared (step A1614), an effect command setting process (step A1615) is performed, and it is determined whether or not the new effect mode is a left-handed mode. (Step A1616).

  If the new effect mode is not a left-handed mode (step A1616; N), the process proceeds to step A1619. If the new effect mode is a left-handed mode (step A1616; Y), a left-handed instruction notification command is prepared (step A1617), and an effect command setting process (step A1618) is performed.

  Then, a flag relating to the time reduction state is loaded from the special figure game mode flag saving area (step A1619), and it is determined whether or not the flag loaded in step A1619 is in the special figure time reduction (step A1620). When the flag loaded in step A1619 is in the special figure time reduction (step A1620; Y), the special figure normal process transition setting process 3 (step A1623) is performed, and the small hit end process is terminated.

  If the flag loaded in step A1619 is not in the special drawing time reduction (step A1620; N), a signal related to the left-handed instruction is saved in the test signal output data area (step A1621). The signal relating to the left-handed instruction is, for example, a signal for turning off the launch position designation signal 1.

  In order to turn off the right-handed display LED, the number in the left-handed state is saved in the game state display number 2 area (step A1622), and the special figure normal process transition setting process 3 (step A1623) is performed. The hit end process ends.

[Special Figure Normal Process Transition Setting Process 3]
Next, details of the special figure normal process transition setting process 3 (step A1623) in the above-described small hit end process will be described with reference to FIG. FIG. 71 is a diagram illustrating a flowchart of the special figure normal process transition setting process 3 according to the first embodiment.

  In the special figure normal process transition setting process 3, first, “0”, which is a process number related to the special figure normal process, is set as a process number (step A1631), and the process number is saved in the special figure game process number area (step A1631). A1632).

  Then, a signal related to the end of the small hit is saved in the external information output data area (step A1633), and a signal related to the end of the small hit is saved in the test signal output data area (step A1634). The signal relating to the end of the small hit is, for example, a signal for turning off one big hit signal. The signal related to the end of the small hit is, for example, a signal for turning off the special symbol small hit signal.

  Then, the information in the variation symbol determination flag area is cleared (step A1635), and the information in the effect mode transition information area is cleared (step A1636). Then, the information of the special figure game mode flag saving area is cleared (step A1637), the illegality monitoring period flag is saved in the special prize opening fraud monitoring period flag area (step A1638), and the special figure normal process transition setting process 3 is executed. finish.

[Direction command setting processing]
Next, details of the effect command setting process in the above-described special figure game process subroutine will be described with reference to FIG. FIG. 72 is a diagram illustrating a flowchart of the effect command setting process according to the first embodiment.

  In the production command setting process, first, the status of the production serial transmission buffer is read (step A1701), and it is determined whether or not the production serial transmission buffer is full (step A1702). If the effect serial transmission buffer is full (step A1702; Y), the process returns to step A1701. If the effect serial transmission buffer is not full (step A1702; N), command data (MODE) is written to the effect serial transmission buffer (step A1703).

  Thereby, the effect command (MODE) is transmitted from the game control device 100 to the effect control device 300 by serial communication using the serial communication function of the CPU 111A in the game control device 100. In the case of this flowchart, the command is transmitted in a 2-byte configuration such as “MODE” and “ACTION”, as in the case of a production command. In those cases, a flowchart corresponding to a plurality of bytes may be used.

The status of the effect serial transmission buffer is read (step A1704), and it is determined whether or not the effect serial transmission buffer is full (step A1705).
If the effect serial transmission buffer is full (step A1705; Y), the process returns to step A1704. If the effect serial transmission buffer is not full (step A1705; N), command data (ACTION) is written into the effect serial transmission buffer (step A1706), and the effect command setting process is terminated.

  By writing the command data (ACTION) into the effect serial transmission buffer, the effect command (ACTION) is transmitted from the game control device 100 to the effect control device 300 by serial communication using the serial communication function of the CPU 111A in the game control device 100. Will be.

  In this way, the effect command (MODE) and the effect command (ACTION) are transmitted from the game control device 100 to the effect control device 300 by serial communication. The production control device 300 receives these commands and performs production control on the screen of the display device 41 or the like. Since the serial communication is performed using the serial communication function of the CPU 111A in the game control apparatus 100, there is an advantage that the configuration is simple.

[Design variation control processing]
Next, details of the symbol variation control process (step A22) in the above-described special figure game process will be described with reference to FIG. FIG. 73 is a diagram illustrating a flowchart of the symbol variation control process according to the first embodiment.

  In the symbol variation control process, first, the target variation control flag is set and it is checked whether the symbol is varying (step A1801), and it is determined whether the symbol is varying as a result of the check (step A1802). .

  If the symbol is changing (step A1802; Y), a symbol display table (for variation) corresponding to the target symbol is acquired (step A1803). Then, the flashing control timer for measuring the variation time of the target symbol is updated by “−1” (step A1804), and it is determined whether or not the flashing control timer is “0” (step A1805).

  When the flashing control timer is “0” (step A1805; Y), the initial value of the flashing control timer corresponding to the target symbol and state is acquired (step A1806), and the initial value of the flashing control timer is set to the target symbol. Save in the blinking control timer area (step A1807). The blinking control timer initial value will be described later with reference to FIG.

  Then, the variable symbol number of the target symbol is updated by “+1” (step A1808), and the process proceeds to step A1809. If the blinking control timer is not “0” (step A1805; N), the process proceeds to step A1809.

  Then, display data corresponding to the value of the variable symbol number area of the target symbol is acquired (step A1809), the acquired display data is saved in the segment area of the target symbol (step A1812), and the symbol variation control process is terminated. To do.

  In step A1802, if not changing (step A1802; N), a symbol display table (for stopping) corresponding to the target symbol is acquired (step A1810). Then, display data corresponding to the value of the stop symbol number area of the target symbol is acquired (step A1811), the acquired display data is saved in the segment area of the target symbol (step A1812), and the symbol variation control process is terminated. To do.

  In addition, on the variation control table prepared in the special figure game process, information on the lower address of the variation control area, the address of the display table 2 (for stoppage), and the address of the display table 1 (for variation) is defined. Yes.

[Blinking control timer initial value table]
Next, details of the blinking control timer initial value (step A1806) acquired by the above-described symbol variation control process will be described with reference to FIG. 74. FIG. 74 is an example of the blinking control timer initial value table of the first embodiment. FIG.

The initial value of the blinking control timer is set for each target symbol (special diagram 1, special diagram 2, general diagram) and its state (state 1, state 2).
The initial value of the blinking control timer is 80 ms when the special figure 1 is in the state 1 and 60 ms when the special figure 1 is in the state 2. The initial value of the blinking control timer is 80 ms when the special figure 2 is in the state 1 and 60 ms when the special figure 2 is in the state 2. The initial value of the blinking control timer is 160 ms when the usual figure is in the state 1 and 120 ms when the usual figure is in the state 2.

  The initial value of the blinking control timer is smaller than the value of state 1 but is not limited to this. The initial value of the blinking control timer may have a larger value in state 2 than in state 1. For example, the initial value of the blinking control timer is 60 ms when special figure 1 is in state 1, 80 ms when special figure 1 is in state 2, and 60 ms when special figure 2 is in state 1. It may be 80 ms when special figure 2 is in state 2, 120 ms when ordinary figure is in state 1, and 160 ms when ordinary figure is in state 2.

  Note that the state 2 is a gaming state that is more advantageous to the player than the state 1, and a specific gaming state can be set for each gaming machine. For example, the gaming machine of the first embodiment corresponds to the state 1 when the special figure 1 or the special figure 2 is not in the probability fluctuation state, and is in the state 2 when the special figure 1 or the special figure 2 is in the probability fluctuation state. Equivalent to.

  As a result, the gaming machine 10 uses the special symbol 1 symbol display unit 53, the special symbol 2 symbol display unit 54, and the universal symbol display unit 55 in addition to the status display unit 57 in the collective display device 50. The status can be displayed.

  In addition, the gaming machine 10 includes a special symbol 1 symbol display unit 53, a special symbol 2 symbol display unit 54, and a general symbol display unit 55 in the collective display device 50 instead of the state display unit 57. Can also be displayed. For example, the gaming machine 10 performs the first state display in the first period in the state display unit 57, performs the second state display in the state display unit 57 in the second period thereafter, and displays the special figure 1 symbol. The first state display can be performed by the unit 53, the special symbol 2 symbol display unit 54, and the universal symbol display unit 55. More specifically, the gaming machine 10 notifies the game state transition (trigger notification) in the state display unit 57 when the game state transitions from the normal state to the probability variation state or the like. In addition, the gaming machine 10 is in the gaming state in the special symbol 1 symbol display unit 53, the special symbol 2 symbol display unit 54, and the general symbol display unit 55 when the gaming state such as the normal state or the probability variation state is a steady state. Is in a steady state (steady state notification). Note that the gaming machine 10 does not necessarily need to notify the gaming state with the special symbol 1 symbol display unit 53, the special symbol 2 symbol display unit 54, and the general symbol display unit 55. The gaming machine 10 may notify the gaming state with one or two of the special symbol 1 symbol display unit 53, the special symbol 2 symbol display unit 54, and the general symbol display unit 55. Further, the gaming machine 10 may notify a more complicated gaming state by a combination of display modes of the special symbol 1 symbol display unit 53, the special symbol 2 symbol display unit 54, and the general symbol display unit 55. . Further, the gaming machine 10 notifies a more complicated gaming state by combining the display forms of the state display unit 57, the special figure 1 symbol display unit 53, the special figure 2 symbol display unit 54, and the general symbol display unit 55. It may be. Therefore, the gaming machine 10 can notify the game progress that is easy for the player to understand.

[Distribution processing]
Next, details of the sorting process (steps A476, A479, A485) in the above-described variation pattern setting process will be described with reference to FIG. FIG. 75 is a diagram illustrating a flowchart of distribution processing according to the first embodiment.

  The sorting process selects the latter half variation selection table of the special figure variation display game from the latter half variation group table based on the variation pattern random number 1, or from the latter half variation selection table (second half variation pattern group) based on the variation pattern random number 2. Processing for selecting the second half variation pattern of the special figure variation display game, or selecting the first half variation pattern of the special figure variation display game from the first half variation selection table (first half variation pattern group) based on the variation pattern random number 3. It is.

  In the distribution process, first, the first data of the prepared latter-half variation group table (selection table), latter-half variation selection table (selection table), and first-half variation selection table (selection table) is a code without distribution (that is, “0”). ) (Step A1901), and as a result of the check, it is determined whether or not the top data is a code without distribution (step A1902). Here, the second-half variation group table, the second-half variation selection table, and the first-half variation selection table store predetermined distribution values in association with at least one second-half variation pattern group, second-half variation pattern, and first-half variation pattern. In the case of a selection table that does not need to be assigned, a sorting value “0”, that is, a code without sorting is defined at the top.

  If the first data in the latter-half variation group table, the latter-half variation selection table, or the first-half variation selection table is an unsorted code (step A1902; Y), update to the address of the data corresponding to the sorting result ( Step A1907), the distribution process is terminated. On the other hand, if the first data of the latter half variation group table, the latter half variation selection table, or the first half variation selection table is not an unsorted code (step A1902; N), the latter half variation group table, the latter half variation selection table, or the first half variation selection table is displayed. One sort value specified first is acquired (step A1903).

  Subsequently, the distribution value obtained in step A1903 from the random number values (variation pattern random number 1, variation pattern random number 2, and variation pattern random number 3) loaded in steps A473, A478, and A484 of the variation pattern setting process. After calculating a new random value by subtraction (step A1904), it is determined whether or not the calculated new random value is smaller than “0” (step A1905). If the new random value is not smaller than “0” (step A1905; N), after updating to the address of the next distribution value (step A1906), the process returns to step A1903.

  That is, in step A1903, after the distribution values specified next in the latter half variation group table, the latter half variation selection table, and the first half variation selection table are acquired, the random number value determined in step A1905 is used as a new random number value. The distribution value is subtracted and a new random value is calculated (step A1904). Then, it is determined whether or not the calculated new random value is smaller than “0” (step A1905). The above processing is executed until it is determined in step A1905 that the new random value is smaller than “0” (step A1905; Y). As a result, at least one latter-half variation selection table, latter-half variation pattern, or first-half variation pattern specified in the latter-half variation group table, the latter-half variation selection table, or the first-half variation selection table is selected. Select the variation number or the first half variation number. If it is determined in step A1905 that the new random value is smaller than “0” (step A1905; Y), the address is updated to the data address corresponding to the result of the distribution (step A1907), and the distribution process ends. To do.

[2-byte sort processing]
Next, details of the 2-byte sorting process (step A475) in the above-described variation pattern setting process will be described with reference to FIG. FIG. 76 is a diagram illustrating a flowchart of 2-byte distribution processing according to the first embodiment.

  The 2-byte distribution process is a process for selecting the latter half variation selection table of the special figure variation display game from the latter half variation group table based on the variation pattern random number 1. As shown in FIG. 76, in the 2-byte sorting process, first, is the leading data of the latter half fluctuation group table (selection table) prepared in the fluctuation pattern setting process a non-sorting code (ie, “0”)? (Step A2001), and as a result of the check, it is determined whether or not the top data is a code without distribution (step A2002). Here, the latter half fluctuation group table stores a predetermined distribution value in association with at least one latter half fluctuation pattern group, but defines only the latter half fluctuation pattern group in which the latter half fluctuation pattern is “no reach”. In the variation group table (for example, a part of the variation group table when the result is out of order), since there is no need for distribution, a distribution value “0”, that is, a code without distribution is defined at the top. .

  If the first data in the latter half variation group table is a code without distribution (step A2002; Y), the data address corresponding to the result of distribution is updated (step A2007), and the 2-byte distribution process is terminated. To do. On the other hand, when the first data in the latter-half variation group table is not a code without distribution (step A2002; N), one distribution value first defined in the latter-half variation group table is acquired (step A2003).

  Subsequently, a new random number value is calculated by subtracting the distribution value acquired in step A2003 from the random value loaded in step A473 of the variation pattern setting process (value of variation pattern random number 1) (step A2004). Then, it is determined whether or not the calculated new random value is smaller than “0” (step A2005). When the new random value is not smaller than “0” (step A2005; N), after updating to the address of the next distribution value (step A2006), the process returns to step A2003. That is, in step A2003, after the distribution value specified next in the variation group selection table is acquired, the distribution value is subtracted using the determined random number as the new random value in step A2005, and a new random value is added. A numerical value is calculated (step A2004). Then, it is determined whether or not the calculated new random value is smaller than “0” (step A2005).

  The above processing is executed until it is determined in step A2005 that the new random value is smaller than “0” (step A2005; Y). As a result, any one of the latter-half variation selection tables is selected from at least one latter-half variation selection table defined in the latter-half variation group table. If it is determined in step A2005 that the new random value is smaller than “0” (step A2005; Y), the address is updated to the data address corresponding to the result of the distribution (step A2007), and the 2-byte distribution process is performed. Exit.

[Normal game processing]
Next, the details of the usual game process (step S130) in the above-described timer interrupt process will be described. FIG. 77 is a diagram illustrating a flowchart of the usual game process according to the first embodiment. In the usual game process, the input of the gate switch 34a is monitored, the entire process related to the usual figure change display game is controlled, the display of the usual figure is set, and the like.

  In this ordinary game process, first, a gate switch monitoring process (step B1) for monitoring the input from the gate switch 34a is performed, and a general power prize switch monitoring process (step B2) for monitoring the input from the start port 2 switch 37a. To do. Next, if the usual game processing timer is not "0", "-1" is updated (step B3). The minimum value of the usual game processing timer is set to “0”. Then, it is determined whether or not the value of the normal game process timer has become “0” (step B4).

  When the value of the usual game process timer is “0” (step B4; Y), that is, when it is determined that the time has expired or has already expired, the process is branched to the process corresponding to the ordinary game process number. A process (step B5) for setting the referenced ordinary game sequence branch table in the register is performed (step B5), and a process (step B6) for acquiring a branch destination address of the process corresponding to the ordinary game process number is performed using the table. . Then, a subroutine call (step B7) is performed with the game process number.

  In step B7, when the game process number is “0”, the fluctuation start of the normal fluctuation display game is monitored, the fluctuation start setting of the normal fluctuation display game, the setting of the effect, and the normal fluctuation process are performed. For this purpose, the usual processing (step B8) for setting information necessary for the purpose is performed. If the game process number is “1” in step B7, a process for changing the normal map (step B9) for setting information necessary for performing the process for displaying the normal map is performed.

  In step B7, if the game process number is “2”, if the result of the general-purpose variable display game is a win, the setting of the open time of the electric power depending on whether the time is short or the A general diagram display process (step B10) is performed for setting information necessary for performing the process during the drawing. In step B7, if the game process number is “3”, the process during the normal map (steps for setting the information necessary to continue the process during the normal map or to perform the baseball remaining ball process) B11) is performed.

  If the game process number is “4” in step B7, the ordinary electric ball remaining ball process (step B12) is performed for setting information necessary for performing the process for ending the normal map. If the game process number is "5" at step B7, a per-figure end process (step B13) is performed for setting information necessary for performing the normal chart process (step B8).

  After that, a general variation control table for controlling the variation of the normal symbol by the general symbol display is prepared (step B14), and the symbol variation control process related to the control of the variation of the normal symbol by the general symbol display (step B15). To complete the ordinary game process. On the other hand, if it is determined in step B4 that the value of the usual game process timer is not 0 (step B4; N), that is, the time is not up, the process proceeds to step B14 and the subsequent processes are performed.

[Gate switch monitoring processing]
Next, details of the gate switch monitoring process (step B1) in the above-described ordinary game process will be described. FIG. 78 is a diagram illustrating a flowchart of gate switch monitoring processing according to the first embodiment. In this gate switch monitoring process, first, it is determined whether or not there is an input to the gate switch 34a (step B101). If there is an input to the gate switch 34a (step B101; Y), it is determined whether or not the game state is a right-handed game (step B102). Here, the right-handed gaming state is during a big hit, during a small hit, or during a special time (short during normal power support). In the case of a game state in which the player strikes right (Step B102; Y), the process proceeds to Step B105. If the game state is not right-handed (step B102; N), a left-handed instruction command is prepared (step B103), an effect command setting process (step B104) is performed, and the number of ordinary drawings held is obtained. Is less than the upper limit (eg, “4”) (step B105).

  When the number of reserved symbols is less than the upper limit (step B105; Y), the number of reserved symbols is updated by “+1” (step B106), and the address of the random number storage area corresponding to the updated number of reserved symbols is updated. Calculate (step B107). The winning random number is extracted and saved in the winning random number storage area of the RWM (step B108), the winning symbol random number is extracted and saved in the winning symbol random number storage area (step B109), and the gate switch monitoring process is terminated.

  Further, when it is determined in step B101 that there is no input to the gate switch 34a (step B101; N), or when it is determined in step B105 that the number of pending drawings is not less than the upper limit value (step B105; N). The gate switch monitoring process is terminated.

[Penden winning switch monitoring process]
Next, the details of the general power winning switch monitoring process (step B2) in the above-described general game process will be described. FIG. 79 is a diagram illustrating a flowchart of the general power winning switch monitoring process according to the first embodiment. In this general power winning switch monitoring process, first, it is determined whether or not the normal figure is being hit, that is, whether or not the normal figure changing display game is in a hit state and the normal variable winning device 37 is executing a predetermined number of releasing operations. Is determined (step B111). If it is normal (step B111; Y), it is determined whether there is an input to the start port 2 switch 37a (step B112), and if there is an input to the start port 2 switch 37a (step B112; Y). If determined, the count number of the utility counter is updated by “+1” (step B113).

  Next, it is determined whether or not the count number of the updated utility counter has reached an upper limit value (for example, “6”) (step B114), and the count number has reached the upper limit value (step B114; Y). When the determination is made, based on the fact that the count of the ordinary power counter has reached the upper limit, as a process for closing the ordinary power, the value of the operation end (for example, “4”) is saved in the control pointer area during the normal figure ( Step B115), the ordinary game processing timer is cleared to zero (Step B116), and the ordinary power prize winning switch monitoring process is terminated. In other words, if there is a pay-per-use prize exceeding the upper limit value during the normal hit state, the hit end value is saved in the middle control processing pointer area at that time, and the normal hit state is not complete. Let it finish.

  Further, when it is determined in step B111 that the normal map is not being reached (step B111; N), if it is determined in step B112 that there is no input to the start port 2 switch 37a (step B112; N), or step B114. When it is determined that the count number has not reached the upper limit value (step B114; N), the ordinary power winning switch monitoring process is terminated.

[Usually normal processing]
Next, the details of the usual figure routine process (step B8) in the above-mentioned usual figure game process will be described. FIG. 80 is a diagram showing a flowchart of ordinary processing in the first embodiment. In this ordinary processing, it is first determined whether or not the number of reserved drawings is “0” (step B121). If the number of reserved drawings is “0” (step B121; Y), The normal process transition setting process 1 (step B141) is performed, and the normal process is terminated. Further, when the usual figure holding number is not “0” (step B121; N), a random number is loaded from the winning random number storage area (for holding number 1) and the winning symbol random number storage area (for holding number 1) (step B122). The winning random number storage area (for holding number 1) and the winning symbol random number storage area (for holding number 1) are cleared to zero (step B123).

  Next, it is determined whether or not the probability of a hit result in the usual fluctuation display game is higher than usual, that is, the time is short (step B124). When the normal probability is not high (step B124; N), a low probability lower limit determination value is set (step B125). When the normal probability is high (step B124; Y), the high probability lower limit determination value is set. Set (step B126). The low probability upper limit determination value and the high probability upper limit determination value are a common value (for example, “251”). Further, the low probability lower limit determination value and the high probability lower limit determination value are different values (for example, the low probability lower limit determination value is “251” and the high probability lower limit determination value is “1”). In comparison, the high probability lower limit determination value is a small value. As a result, the hit probability increases at a high probability as compared with a low probability, and is, for example, 0/251 when the probability is low and 250/251 when the probability is high.

  Next, it is determined whether or not the hit random number is equal to or greater than the upper limit determination value (step B127). If the hit random number is not equal to or greater than the upper limit determination value (step B127; N), whether or not the hit random number is less than the lower limit determination value. Is determined (step B128). In step B127, when the hit random number is greater than or equal to the upper limit determination value (step B127; Y), or in steps B127 and B128, the hit random number is less than the lower limit determination value (step B127; N, step B128; Y), that is, In the case of a miss, the slip information is saved in the hit flag area (step B129), the slip stop symbol number is set (step B130), and the slip symbol information is saved in the normal symbol stop symbol information area (step B131). In steps B127 and B128, if the winning random number is less than the upper limit determination value and greater than or equal to the lower limit determination value, that is, if it is a hit (step B127; N, step B128; N), the hit information is saved in the hit flag area ( In step B132), a hit stop symbol number corresponding to the loaded hit symbol random number is set (step B133), and stop symbol information corresponding to the stop symbol number is saved in the normal symbol stop symbol information area (step B134). In the first embodiment, there are three types of winning symbols.

  Next, the stop symbol number is saved in the normal symbol stop symbol area (step B135), and the stop symbol number is saved in the test signal output data area (step B136). After that, the random number storage area per usual figure is shifted (step B137), the free area after the shift is cleared to zero (step B138), and the usual figure holding number is updated by "-1" (step B139). That is, in accordance with the execution of the usual map change display game related to the oldest number of held maps 1, the ranking of the number of held maps “2” to “4” that is held after the number of held maps “1” The process of moving up one by one is performed. As a result of this processing, the value for the number of reserved maps in the random number storage area from 2 to 4 is shifted from the value for the number of reserved maps in the random number storage area to 1 for the number of reserved maps in the random number storage area. Will be. Then, the value for the number of reserved customary numbers 4 in the random number storage area per common number is cleared, and the number of reserved general figure numbers is decremented by “1”.

Then, a normal process transition setting process (step B140) is performed, and the normal chart normal process is terminated.
[Usual map transition setting process 1]
Next, the details of the normal figure normal process transition setting process 1 (step B141) in the above normal figure normal process will be described. FIG. 81 is a diagram illustrating a flowchart of the normal routine transition setting process 1 according to the first embodiment. In this normal figure normal process transition setting process 1, first, “0” is set as the process number for shifting to the normal figure normal process (step B151), and the process number is saved in the normal figure game process number area (step B151). B152). Thereafter, the fraud monitoring period flag is saved in the ordinary power fraud monitoring period flag area (step B153), and the normal figure normal process transition setting process 1 is terminated.

[Process transition setting process during normal map change]
Next, the details of the process transition setting process (step B140) during the normal map change in the above normal map normal process will be described. FIG. 82 is a diagram illustrating a flowchart of a process for setting a process for changing a normal map according to the first embodiment. In the process for changing the process for changing the normal map, first, “1” is set as the process number for shifting to the process for changing the normal figure (step B161), and the process number is saved in the normal game process number area ( In step B162), the normal time change time (common to low probability and high probability (for example, 500 ms)) is saved in the normal game processing timer area (step B163). After that, a signal related to the start of the normal variable display game is saved in the test signal output data area (step B164). It should be noted that the signal related to the start of the normal symbol variation display game is a signal for turning on the normal symbol 1 variation signal.

  Next, a changing flag indicating that the normal fluctuation display game is changing is saved in the normal fluctuation control flag area (step B165). Then, the flashing control timer initial value (for example, 100 ms), which is the initial value of the flashing cycle timer of the general display indicator, is saved in the general flashing control timer area (step B166), and the transition processing setting process for the normal map change process is performed. finish.

[Processing during normal map changes]
Next, the process during normal map change (step B9) in the above general game process will be described. FIG. 83 is a diagram illustrating a flowchart of the normal-variation process according to the first embodiment. In this normal map change process, the normal map display process transition setting process (step B171) is performed, and the normal map change process is terminated.

[Transition setting process during normal map display]
Next, the details of the process for setting the transition to the normal map display process (step B171) in the process for changing the normal map will be described. FIG. 84 is a diagram illustrating a flowchart of a process for setting a transition to a normal map display according to the first embodiment. In this normal chart display process transition setting process, first, the process number is set to "2" as a setting process for transitioning to the general chart display process (step B181), and the process number is set in the general game process number area. Save (step B182). Thereafter, the usual game display time (for example, 600 ms) is saved in the usual game process timer area (step B183). Further, a signal related to the end of fluctuation is saved in the test signal output data area (step B184). Note that the signal related to the end of the normal variation is a signal for turning off the normal symbol 1 variation signal.

Next, a stop flag indicating that the normal map change display game is stopped is saved in the normal map change control flag area (step B185), and the normal display display process transition setting process is terminated.
[Processing during normal map display]
Next, the details of the normal map display process (step B10) in the above-described normal game process will be described. FIG. 85 is a diagram illustrating a flowchart of a normal map display process according to the first embodiment. In the process of displaying a normal map, first, the hit flag (hit information or disappointment information) set in the normal map normal process is loaded (step B191), and the RWM hit flag area information is cleared (step B192). ), It is determined whether or not the loaded hit flag is hit information (step B193).

  If the hit flag is not hit information (step B193; N), the normal figure normal process transition setting process 1 (step B198) for shifting to the normal figure normal process is performed, and the normal figure display process is terminated. This normal figure normal process transition setting process 1 is the process shown in FIG. On the other hand, if the hit flag is hit information (step B193; Y), a hit process setting table is set (step B194).

  Then, a hit start pointer value (one of control pointers “0”, “2”, “4”) corresponding to the normal stop symbol information is acquired and saved in the normal pointer control pointer area (step B195), The general electric circuit opening time (500 ms or 1700 ms) corresponding to the general map stop symbol information is acquired and saved in the general graphic game processing timer area (step B196). As a result, the opening mode of the normal variation winning device 37 in the short-time state is set, and for example, it is possible to open four times. After that, a normal process transition setting process (step B197) is performed, and the normal chart display process is terminated.

[Normal processing transition setting process per ordinary figure]
Next, the details of the process for setting the transition to the normal map process (step B197) in the process for displaying the normal map will be described. FIG. 86 is a diagram illustrating a flowchart of the normal process transition setting process according to the first embodiment. In this normal process transition setting process, first, “3” is set as the process number for shifting to the normal process (step B201), and the process number is saved in the normal game process number area. (Step B202). After that, a signal related to the start of the hitting of the normal fluctuation display game (signal related to the hit of the normal fluctuation display game) and a signal relating to the start of the normal electric operation are saved in the test signal output data area (step B203). It should be noted that the signal related to the start of the normal figure change display game is a signal for turning on the normal signal per symbol, and the signal relating to the start of the normal electric operation is a signal for turning on the signal for operating the normal electric accessory 1 It is.

Next, in order to output a signal for driving (turning on) the ordinary electric solenoid, ON data is saved in the ordinary electric solenoid output data area (step B204).
In addition, the information on the normal power count number area for storing the number of winnings to the normal variation winning device 37 is cleared (step B205), and the normal power illegality for storing the number of winnings to the normal variation winning device 37 during the normal power fraud monitoring period. The information on the winning area is cleared (step B206). Then, a flag that defines the outside of the fraud monitoring period of the normal variation winning device 37 is saved in the ordinary power fraud monitoring period flag area (step B207), and the normal process transition setting process is terminated.

[Usual processing per map]
Next, the details of the process for hitting the usual figure (step B11) in the above-mentioned usual figure game process will be described. FIG. 87 is a diagram illustrating a flowchart of the normal hit processing according to the first embodiment. In this process for normal maps, first, a control pointer for normal maps is loaded and prepared (step B211), and the value of the loaded control pointer for normal maps is the value of the upper limit value area for control pointers for normal maps. It is determined whether or not (the value of hit end) has been reached (step B212).

  If the value of the control pointer during the normal map does not reach the value of the control pointer upper limit value area during the normal map (step B212; N), the control pointer during the normal map is updated by "+1" (step B213). Then, the ordinary electric operation transition setting process (step B214) is performed, and the process during the normal figure is terminated. Further, when the value of the control pointer during normal map reaches the value of the control pointer upper limit value area during normal map (the value of end of hit) (step B212; Y), step B213 is passed and the normal power operation transition setting is made. A process (step B214) is performed, and the process during the normal drawing is terminated.

[Normal electric operation transition setting process]
Next, the details of the normal power operation transition setting process (step B214) in the above-described normal process will be described. FIG. 88 is a diagram illustrating a flowchart of a normal power operation transition setting process according to the first embodiment. This normal electric operation transition setting process is a process for performing drive control of the normal electric solenoid 37c for opening and closing the normal variation winning device 37, and the process branches according to the value of the control pointer. In this ordinary power operation transition setting process, first, a branching process corresponding to the value of the control pointer is performed (step B221).

  If the value of the control pointer is “0” or “2”, the process proceeds to step B222. That is, in order to control the closing of the normal variation winning device 37, the wait time (for example, 200 ms) after the closing of the normal variation winning device 37 corresponding to the control pointer is saved in the normal game processing timer area (step B222). In order to turn off the general electric solenoid 37c, the off data is saved in the general electric solenoid output data area (step B223), and the general electric operation transition setting process is terminated.

  If the value of the control pointer is “1” or “3”, the process proceeds to step B224. That is, in order to control the release of the normal variation winning device 37, the normal power release time (for example, 1700 ms), which is the opening time of the normal variation winning device 37 corresponding to the control pointer, is saved in the normal game processing timer area (step B224), ON data is saved in the normal power solenoid output data area in order to turn ON the general power solenoid 37c (step B225), and the general power operation transition setting process is terminated.

  If the value of the control pointer is “4”, the process proceeds to step B226. That is, “4” is set as the process number (step B226) in order to end the opening control of the normal variation winning device 37 and perform the ordinary electric ball remaining ball process (step B12). Then, this processing number is saved in the ordinary game processing number area (step B227), and the ordinary electric ball remaining time (for example, 600 ms) is saved in the ordinary game processing timer area (step B228). Thereafter, in order to turn off the general electric solenoid 37c, the off data is saved in the general electric solenoid output data area (step B229), and the normal electric operation transition setting process is ended.

  Next, the ordinary power operation in the normal variation winning device 37 of the first embodiment will be described with reference to FIG. FIG. 89 is a diagram showing a general electric operation timing chart of the normal variation winning device of the first embodiment. In the figure, the numbers in the squares indicate the values of the control pointers.

  The normal electric operation in the case of the winning symbol 1 in the normal variation winning device 37 is a total of 1200 ms consisting of the normal display time (600 ms), the subsequent general electric power release time (500 ms), and the remaining ball processing time (600 ms) thereafter. It is a series of operations. In the case of winning symbol 1, the value of the control pointer becomes “4” after the normal power release time elapses, and the normal power remaining ball processing is performed after the normal variable winning device 37 is released once.

  In addition, the normal power operation in the case of the winning symbol 2 in the normal variation winning device 37 is as follows: the normal signal display time (600 ms), the subsequent normal power release time (1700 ms), the subsequent wait time (200 ms), and the subsequent This is a series of operations for a total of 4800 ms, consisting of the open time (1700 ms) and the remaining ball processing time (600 ms). In the case of the winning symbol 2, the control pointer value becomes “2” after the first public power open time elapses, and the control pointer value passes through the processes corresponding to “2” and “3”. The value of the pointer is “4”. In this way, in the case of the winning symbol 2, the ordinary power remaining ball processing is performed after the two opening operations of the normal variation winning device 37.

  In addition, the normal power operation in the case of the winning symbol 3 in the normal variation winning device 37 is as follows: the normal signal display time (600 ms), the subsequent normal power release time (1700 ms), the subsequent wait time (200 ms), and the subsequent This is a series of operations for a total of 6700 ms, which is composed of a normal power release time (1700 ms), a subsequent wait time (200 ms), a subsequent general power release time (1700 ms), and a remaining ball processing time (600 ms). In the case of winning symbol 3, the value of the control pointer becomes “0” after the first public power open time elapses, and the values of the control pointer correspond to “0”, “1”, “2”, “3”. After each process, the value of the control pointer becomes “4”. In this way, in the case of the winning symbol 3, the ordinary electric ball remaining ball process is performed after the opening operation of the normal variation winning device 37 three times.

  Note that, during the normal time display time, the wait time, and the remaining ball processing time, the normal variation winning device 37 is closed by the off control of the general electric solenoid 37c. In addition, during the normal power release time, the normal variation winning device 37 is opened by turning on the general power solenoid 37c.

[Penden residual ball processing]
Next, the ordinary power remaining ball process (step B12) in the above-described ordinary game process will be described. FIG. 90 is a diagram illustrating a flowchart of the ordinary electric ball remaining ball process according to the first embodiment. In this ordinary electric ball remaining ball process, the normal electric power end ball shift setting process (step B231) is performed, and the electric power remaining ball process is terminated.

[Usual map end process transition setting process]
Next, the details of the normal signal end process transition setting process (step B231) in the above-described ordinary electric power remaining ball process will be described. FIG. 91 is a diagram illustrating a flowchart of a universal hit process transition setting process according to the first embodiment. In this normal figure end process transition setting process, first, the process number “5” related to the general figure end process is set (step B241), and the process number is saved in the normal game process number area (step B242). ).

  Thereafter, the normal ending time (for example, 100 ms) is saved in the normal game processing timer area (step B243), and a signal related to the end of the operation of the normal variation winning device 37 is saved in the test signal output data area (step B244). The signal related to the end of the operation of the normal variation winning device 37 is a signal for turning off the normal electric accessory 1 operating signal.

  Next, the information in the general electric power count number area for counting the number of winnings to the normal variation winning device 37 is cleared (step B245). Then, the value of the control pointer area during normal drawing is cleared (step B246), and the normal drawing end processing transition setting processing is ended.

[End processing per regular map]
Next, the normal figure end process (step B13) in the above-described general figure game process will be described. FIG. 92 is a view illustrating a flowchart of the universal hit end process according to the first embodiment. In this normal figure end process, the normal figure normal process transition setting process 2 (step B251) is performed, and the normal figure end process ends.

[Usuzu usual process transition setting process 2]
Next, the details of the normal figure normal process transition setting process 2 (step B251) in the above-described normal figure end process will be described. FIG. 93 is a diagram illustrating a flowchart of the normal routine process transition setting process 2 according to the first embodiment. In this normal figure normal process transition setting process 2, first, the process number “0” related to the normal figure normal process is set (step B261), and the process number is saved in the normal figure game process number area (step B262). .

  Thereafter, a signal relating to the end of hitting of the normal game is saved in the test signal output data area (step B263). It should be noted that the signal related to the end of the normal-game variable game is a signal for turning off the normal symbol 1 variable signal.

  After that, a flag that defines the fraud monitoring period of the normal variation winning device 37 (flag during fraud monitoring period) is saved in the ordinary power fraud monitoring period flag area (step B264), and the normal chart normal process transition setting process 2 is terminated. .

[Segment LED editing processing]
Next, details of the segment LED editing process (step S131) in the timer interrupt process described above will be described with reference to FIG. FIG. 94 is a diagram illustrating a flowchart of segment LED editing processing according to the first embodiment. In the segment LED editing process, settings relating to driving of the LEDs constituting the round display section 51, the special figure 1 hold display section 52, the general figure hold display section 56, and the status display section 57 provided in the batch display device 50, etc. To do.

In the segment LED editing process, first, the flashing control timer is updated by adding “1” (step C11). The blinking control timer is, for example, an 8-bit counter timer.
Next, the output hold timing of the general map hold display is determined (step C12). If it is the output on timing (step C12; Y), the general map hold number display table 1 is set (step C13), and the output on timing is set. If not (step C12; N), the general figure hold number display table 2 is set (step C14). It should be noted that the determination of the output on timing of the usual map hold display can be made by referring to a specific bit of the timer. For example, a blinking period of 128 ms can be set by referring to the fifth bit of the timer incremented by 1 every 4 ms.

  Thereafter, display data corresponding to the number of reserved general maps is acquired from the set general map hold number display table 1 or the general map hold number display table 2, and saved in the segment area (step C15). The segment area is a storage area for storing display data of LED_00 to LED_31.

  For example, the common figure hold number display table 1 and the common figure hold number display table 2 have the same values for the common figure hold numbers “0” to “2”, but different values for the common figure hold numbers “3” and “4”. It is. As a result, in the general map hold display unit 56, the corresponding LED is turned off when the general map hold number is “0”, the corresponding LED is turned on when the general map hold number is “1”, “2”, and the general map hold number is “3”. , “4” realizes blinking of the corresponding LED.

  Next, the output on timing of the special figure 1 hold display is determined (step C16), and if it is the output on timing (step C16; Y), the special figure 1 hold number display table 1 is set (step C17) and output. When it is not the on-timing (step C16; N), the special figure 1 hold number display table 2 is set (step C18). Note that the determination of the output on timing of the special figure 1 hold display can be made the same as the determination of the output on timing of the general figure hold display. At this time, for example, by changing the reference bit of the timer that is incremented by 1 every 4 ms from the normal hold display, it is possible to set a blinking cycle different from the normal hold display.

  Thereafter, display data corresponding to the special figure 1 hold number is acquired from the set special figure 1 hold number display table 1 or the special figure 1 hold number display table 2 and saved in the segment area (step C19). Note that the special figure 1 hold display section 52 also realizes the LED lighting mode in the same manner as the general figure hold display section 56.

  Next, the output on timing of the special figure 2 hold display is determined (step C20), and if it is the output on timing (step C20; Y), the special figure 2 hold number display table 1 is set (step C21) and output. When it is not the on-timing (step C20; N), the special figure 2 hold number display table 2 is set (step C22). Note that the determination of the output on timing of the special figure 2 hold display can be made the same as the determination of the output on timing of the general figure hold display. At this time, for example, by changing the reference bit of the timer that is incremented by 1 every 4 ms from the normal hold display, it is possible to set a blinking cycle different from the normal hold display.

  Thereafter, display data corresponding to the special figure 2 hold number is acquired from the set special figure 2 hold number display table 1 or the special figure 2 hold number display table 2 and saved in the segment area (step C23). The special figure 2 hold display section 58 also realizes the LED lighting mode in the same manner as the general figure hold display section 56.

  Further, a round display LED display table in which the display mode in the round display unit 51 is defined is set (step C24), display data corresponding to the round display LED output pointer is acquired, and saved in the segment area (step C25). .

Next, the game state display table 1 is set (step C26), display data corresponding to the game state display number 1 is acquired, and saved in the segment area (step C27).
The game status display table 1 indicates whether or not the game status of the special figure game is short in time (supporting ordinary power), in other words, whether or not it is one of the game status advantageous to the player. The display mode for the display unit 57 to notify is defined. For example, when the LED_29 in the status display unit 57 is turned off, “normal” is notified, and when the LED_29 is turned on, “special time is short (medium power support is in progress)”.

  Thereafter, the game state display table 2 is set (step C28), display data corresponding to the game state display number 2 is acquired, saved in the segment area (step C29), and the segment LED editing process is terminated.

  The game state display table 2 indicates whether or not the game state of the special figure game is a right-handed game state, in other words, whether or not it is another game state advantageous to the player. Defines the display mode for notification. For example, “normal strike (left-handed)” is notified when LED_30 in the status display section 57 is turned off, and “right-handed” is notified when LED_30 is turned on. It should be noted that the period for notifying “right-handed” includes periods corresponding to gaming states such as during big hits, during small hits, and during normal power support.

  Thereby, segment LED edit processing can alert | report a game progress to a player with the set display mode. Accordingly, the round display unit 51, the special figure 1 hold display part 52, the special figure 2 hold display part 58, the general figure hold display part 56, and the status display part, which are display mode setting targets by the segment LED editing process. 57 has a function as a game progress notification unit.

  Next, magnet fraud monitoring processing and panel radio wave fraud monitoring processing for monitoring fraud will be described. A gaming machine that gives a player a predetermined game value according to the result of the game may be cheated to illegally obtain the game value. Among such fraudulent acts, gaming machines equipped with a mechanism for detecting fraudulent acts using magnets are conventionally known. There are various types of fraud, and detection methods and conditions corresponding to each type are necessary. However, the occurrence of an abnormal condition could not be accurately detected.

  In particular, misjudging that an abnormal condition has occurred despite the fact that no abnormal condition has occurred has led to mistrust of the player, and is a cause of game evasion in the gaming machine. Therefore, it is important not to perform erroneous detection of such an abnormal state.

  Therefore, the gaming machine 10 accurately detects the occurrence of an abnormal state based on the magnetic detector that detects abnormal magnetism, the radio wave detector that detects abnormal radio waves, and the detection results of the magnetic detector and radio wave detector. For example, the following magnet fraud monitoring process and panel radio wave fraud monitoring process are performed for the purpose of preventing erroneous detection of an abnormal state.

[Magnetic fraud monitoring processing]
First, the magnet fraud monitoring process (step S132) in the above-described timer interrupt process will be described with reference to FIG. FIG. 95 is a diagram illustrating a flowchart of the magnet fraud monitoring process according to the first embodiment. In the magnet fraud monitoring process, the presence / absence of an abnormality is determined based on the detection signal from the magnetic sensor 61 that constitutes a magnetic detector that detects abnormal magnetism, and fraud notification is started and ended. In addition, since a magnetic detector functions as a magnet detector which detects the approach of a magnet, a magnetic sensor can be paraphrased as a magnet sensor.

  In the magnet fraud monitoring process, first, from the state of the detection signal output from the magnetic sensor 61 and taken into the third input port 124 (input port 3), is the magnetic sensor turned on, that is, whether abnormal magnetism has been detected? It is determined whether or not (step C31). When the magnetic sensor is on (step C31; Y), that is, when abnormal magnetism is detected, "1" is added to the magnet fraud monitoring timer for measuring the abnormal magnetism detection period and updated (step C32). ), It is determined whether or not the magnet fraud monitoring timer has expired (step C33).

  When the magnet fraud monitoring timer expires (step C33; Y), that is, when abnormal magnetism is continuously detected for a certain period (for example, 32 ms), the abnormality is determined. When an abnormality is determined, the magnet fraud monitoring timer is cleared (step C34), and the magnet fraud notification timer initial value (for example, 60000 ms) is saved in the magnet fraud notification timer area (step C35). Then, a magnet fraud notification command is prepared (step C36), a magnet fraud occurrence flag is prepared as a magnet fraud flag (step C37), and whether or not the prepared magnet fraud flag matches the value of the magnet fraud flag area. Determine (step C43).

  That is, the game control device 100 has a function as an abnormal state detection control unit that detects an abnormal state based on the detection result of the magnetic sensor. The game control apparatus 100 determines that an abnormal state has occurred when the magnetic sensor continuously detects abnormal magnetism over a predetermined period.

  On the other hand, when the magnetic sensor is not on (step C31; N), that is, when no abnormal magnetism is detected, the magnet fraud monitoring timer is cleared (step C38), and the magnet fraud notification that defines the magnet fraud notification time is provided. If the timer is not "0", "1" is subtracted from the magnet fraud notification timer and updated (step C39). Note that the minimum value of the magnet fraud notification timer is set to “0”. Then, it is determined whether or not the value of the magnet fraud notification timer is “0” (step C40). In addition, also when the magnet fraud monitoring timer has not timed up (step C33; N), it transfers to the process of step C39.

  When the value of the magnet fraud notification timer is not “0” (step C40; N), that is, when the time has not expired, the magnet fraud monitoring process is terminated. Further, when the value of the magnet fraud notification timer is “0” (step C40; Y), that is, when the time has been up or when the time has already expired and the fraud notification period has ended, If no fraud notification has been made, a command for terminating magnet fraud notification is prepared (step C41). Further, a magnet fraud release flag is prepared as a magnet fraud flag (step C42), and it is determined whether or not the prepared magnet fraud flag matches the value of the magnet fraud flag region (step C43).

  If the prepared magnet fraud flag matches the value of the magnet fraud flag area (step C43; Y), the magnet fraud monitoring process is terminated. If the values do not match (step C43; N), the prepared magnet fraud flag is saved in the magnet fraud flag area (step C44), a production command setting process is performed (step C45), and the magnet fraud monitoring process is terminated. To do.

[Board radio fraud monitoring processing]
Next, details of the board radio wave fraud monitoring process (step S133) in the timer interrupt process described above will be described with reference to FIG. FIG. 96 is a diagram illustrating a flowchart of board radio wave fraud monitoring processing according to the first embodiment. In the panel radio wave fraud monitoring process, the presence / absence of an abnormality is determined based on a detection signal from the panel radio wave sensor 62 that forms a radio wave detector that detects an abnormal radio wave, and fraud notification is started or stopped.

  In the board radio wave fraud monitoring processing, first, the board radio wave sensor is turned on from the state of the detection signal output from the board radio wave sensor 62 and taken into the third input port 124 (input port 3) via the proximity I / F 121. That is, it is determined whether or not an abnormal radio wave is detected (step C51). When the panel radio wave sensor is on (step C51; Y), that is, when an abnormal radio wave is detected, the radio wave fraud notification timer initial value (for example, 60000 ms) is saved in the radio wave fraud notification timer area (step C52).

  Then, a board radio fraud notification command is prepared (step C53), a board radio fraud occurrence flag is prepared as a board radio fraud flag (step C54), and the prepared board radio fraud flag is set to the value of the board radio fraud flag area. It is determined whether they match (step C59). That is, in the case of radio wave fraud, unlike the case of magnetic fraud, it is determined that an abnormality has occurred when an abnormal radio wave is detected.

  That is, the game control device 100 has a function as an abnormal state detection control unit that detects the occurrence of an abnormal state based on the detection result of the board radio wave sensor. Then, the game control device 100 determines that an abnormal state has occurred only when the board radio wave sensor detects a single abnormal radio wave.

  On the other hand, if the panel radio wave sensor is not on (step C51; N), that is, if no abnormal radio wave is detected, the radio wave fraud notification is not performed unless the radio wave fraud notification timer that defines the radio wave fraud notification time is “0”. The timer is updated by subtracting “1” (step C55). The minimum value of the radio wave unauthorized notification timer is set to “0”. Then, it is determined whether or not the value of the radio wave fraud notification timer is “0” (step C56).

  If the value of the radio wave fraud notification timer is not “0” (step C56; N), that is, if the time is not up, the board radio wave fraud monitoring process is terminated. In addition, when the value of the radio wave unauthorized notification timer is “0” (step C56; Y), that is, when the time is up or when the time has already expired and the period of the unauthorized notification ends, If no fraud notification has been made, a command to terminate board radio fraud notification is prepared (step C57), and a board radio fraud release flag is prepared as a board radio fraud flag (step C58). It is determined whether or not the flag matches the value in the board radio wave fraud flag area (step C59).

  When the prepared board radio wave fraud flag matches the value of the board radio wave fraud flag area (step C59; Y), the board radio wave fraud monitoring process is terminated. If the values do not match (step C59; N), the prepared board radio wave fraud flag is saved in the board radio wave fraud flag area (step C60), a production command setting process is performed (step C61), and the board radio wave fraud monitoring is performed. End the process.

  By performing the magnet fraud monitoring process and the panel radio wave fraud monitoring process as described above, it is possible to accurately detect the occurrence of an abnormal state. In other words, a gaming machine is equipped with a component that generates magnetism, such as a solenoid, but when it detects magnetism continuously over a predetermined period of time, it is determined to be in an abnormal state. Generation can be prevented from being erroneously detected as an abnormal state. On the other hand, since the gaming machine is not equipped with a component that emits radio waves, it is possible to minimize damage by immediately determining that an abnormal radio wave is detected as an abnormal state.

  In the first embodiment, the detection of abnormal magnetism is simply a state in which magnetism is detected. However, it may be a state in which magnetism stronger than the magnetic state in a state that is not in an abnormal state is detected, or a predetermined threshold value or more. The state in which magnetism is detected may be abnormal. In the first embodiment, abnormal radio waves are detected simply by receiving a radio wave. However, the radio waves may not be received in an abnormal state or received in an abnormal state. It is good also as the state which received the electromagnetic wave of the frequency which is not. Moreover, it is good also considering the state which detected the electromagnetic wave whose intensity | strength is more than a predetermined threshold, or the electromagnetic wave of a specific frequency as abnormality. When the threshold value is set based on the strength of the magnetic field, the strength of the radio wave, or the frequency, a signal may be output when the threshold value is exceeded on the magnetic sensor 61 or the panel radio wave sensor 62 side, or the threshold value may be set on the control device side. You may make it monitor whether it exceeded.

  From the above, the detection results of the magnetic detector (magnetic sensor 61) for detecting abnormal magnetism, the radio wave detector (panel radio wave sensor 62) for detecting abnormal radio waves, and the magnetic detector and radio wave detector And an abnormal state detection control means (game control device 100) for detecting the occurrence of an abnormal state, and the abnormal state detection control means detects abnormal magnetism continuously for a predetermined period in the case of a magnetic detector. In this case, it is determined that an abnormal state has occurred. However, in the case of a radio wave detector, it is determined that an abnormal state has occurred once an abnormal radio wave is detected.

[External information editing process]
Next, details of the external information editing process (step S134) in the above-described timer interrupt process will be described with reference to FIGS. 97 and 98. FIG. FIG. 97 is a first diagram illustrating a flowchart of external information editing processing according to the first embodiment. FIG. 98 is a second diagram illustrating a flowchart of external information editing processing according to the first embodiment.

  In the external information editing process, the monitoring results in the payout command transmission process (step S125), the winning opening switch / status monitoring process (step S128), the magnet fraud monitoring process (step S132), and the panel radio wave fraud monitoring process (step S133) are displayed. Based on this, information to be output to an external device such as an information collection terminal or a game hall internal management device or a test firing test device is created and set in an output buffer.

  In the external information editing process, first, a process for setting information according to an error state or a security state is performed. In the process of setting information according to the error state and the security state, when a glass frame opening error is occurring (step C71; Y) and a main body frame opening error is occurring (step C72; Y), the door / frame The ON signal of the release signal is saved in the external information output data area (step C73), and the ON data of the gaming machine error state signal is saved in the test signal output data area (step C74). That is, the occurrence of the glass frame opening error and the main body frame opening error is output as external information and a test signal.

  On the other hand, if neither the glass frame opening error nor the body frame opening error has occurred (steps C71 to C72; N), the off-data of the door / frame opening signal is saved in the external information output data area (step S71). C75), the off-data of the security signal is saved in the external information output data area (step C76).

  Next, if the security signal control timer that counts a predetermined time (for example, 256 ms) from when the data stored in the RAM is initialized by operating the initialization switch or the like is updated to “−1”. (Step C77). The minimum value of the security signal control timer is set to “0”. Then, it is determined whether or not the value of the security signal control timer is “0” (step C78).

  When the value of the security signal control timer is not “0” (step C78; N), that is, when the time is not up, the on-data of the security signal is saved in the external information output data area (step C79). On the other hand, when the value of the security signal control timer is “0” (step C78; Y), that is, when the time is up, the process of step C79 is passed. In other words, the initialization of the data stored in the RAM is output as external information until the security signal control timer expires.

  Magnet fraud (step C80; Y), board radio fraud (step C81; Y), frame radio fraud (step C82; Y), ordinary electric fraud (step C83; Y), or a grand prize When mouth fraud is occurring (step C84; Y), the ON data of the security signal is saved in the external information output data area (step C85), and the ON data of the gaming machine error status signal is saved in the test signal output data area. (Step C86).

  On the other hand, if none of the magnet fraud, board radio fraud, frame radio fraud, general power fraud, or special prize opening fraud has occurred (steps C80 to C84; N), the off-state data of the gaming machine error status signal is tested. Save in the signal output data area (step C87).

  Next, in the external information editing process, a main prize ball signal editing process (step C88) for setting information related to the number of prize balls to be paid out is performed, and a starting hole signal editing process (step C89) for editing a winning signal at the starting hole. To do. Next, if the symbol determination number control timer for controlling the output time of the information related to the number of times of execution of the special figure variation display game is not “0”, “−1” is updated (step C90). Note that the minimum value of the symbol determination frequency control timer is set to “0”. Then, it is determined whether or not the value of the symbol determination number control timer is “0” (step C91).

  When the value of the symbol determination count control timer is “0” (step C91; Y), that is, when the time is up or when the time has already expired, the off data of the symbol determination frequency signal is stored in the external information output data area. Save (step C92), the external information editing process is terminated. On the other hand, if the value of the symbol determination count control timer is not “0” (step C91; N), that is, if the time is not up, the on data of the symbol determination count signal is saved in the external information output data area (step S91). C93), the external information editing process is terminated.

[Main prize ball signal editing process]
Next, details of the main prize ball signal editing process (step C88) in the external information editing process described above will be described with reference to FIG. FIG. 99 is a diagram illustrating a flowchart of the main prize ball signal editing process according to the first embodiment. The main prize ball signal editing process is a main prize ball signal generated every time the number of prize balls (scheduled number to be paid out, scheduled game medium payout number) generated by winning the winning a prize becomes a predetermined number (here, 10). Is output to the external device.

  In the main prize ball signal editing process, first, if the main prize ball signal output control timer is not “0”, “−1” is updated (step C101). The minimum value of the main prize ball signal output control timer is set to “0”. Then, it is determined whether or not the value of the main prize ball signal output control timer is “0” (step C102). When the value of the main prize ball signal output control timer is “0” (step C102; Y), it is determined whether or not the number of main prize ball signal outputs is “0” (step C103).

  If the main prize ball signal output count is not “0” (step C103; N), the main prize ball signal output count is updated by “−1” (step C104), and the main prize ball signal output control timer area is updated to the main prize ball signal output control timer area. The initial value of the prize ball signal output control timer is saved (step C105). The initial value of the main prize ball signal output control timer is obtained by adding the time (eg, 128 ms) of the on state (eg, high level) of the main prize ball signal and the time (eg, 64 ms) of the off state (eg, low level). It is time (for example, 192 ms). Thereafter, on data for turning on the main prize ball signal is saved in the external information output data area of the RWM (step C107), and the main prize ball signal editing process is terminated. If the main prize ball signal output count is 0 (step C103; Y), off data for turning off the main prize ball signal for the external device is saved in the external information output data area of the RWM (step S103). C108), the main prize ball signal editing process is terminated.

  On the other hand, when the value of the main prize ball signal output control timer is not 0 (step C102; N), it is determined whether the main prize ball signal output control timer is in the output on period (step C106). Note that the main prize ball signal output control timer is in the output-on period means that the value of the main prize ball signal output control timer is equal to or longer than a predetermined time (for example, 64 ms). If the main prize ball signal output control timer is in the output ON period (step C106; Y), the process proceeds to step C107. If the main prize ball signal output control timer is not in the output on period (step C106; N), off data for turning off the main prize ball signal for the external device is saved in the external information output data area of the RWM. (Step C108), the main prize ball signal editing process is terminated.

  Through the above processing, information related to the scheduled game medium payout number is transmitted to the outside. After the payout condition based on the game ball winning is established, it is faster to generate and send the main prize ball signal than to complete the payout of the game ball by operating the payout device. Between the time when the payout condition is satisfied and the time when the number of game media to be paid out is paid out, information related to the planned number of game media payouts, which is the number of game media to be paid out, is output to the outside.

  That is, the game control device 100 can output information on the planned number of game media payouts, which is the number of game media to be paid out, after the payout conditions are satisfied and before paying out the number of game media to be paid out. To provide an external output means.

  However, if the number of award balls generated is small, and if this amount is not less than a predetermined number (for example, 10) even if it is added to the value of the remaining number of award balls, information on the expected number of game media payouts after the actual payout has been completed May be output. By reducing the unit of the scheduled game medium payout number corresponding to one main prize ball signal (for example, “1”), the payout condition is always satisfied until the payout number of game media is paid out. In the meantime, it is also possible to output information related to the scheduled number of game media payouts, which is the number of game media scheduled to be paid out.

  From the above, a payout device (payout unit) capable of paying out game media, and control means (game control) for controlling the payout device to pay out a predetermined amount of game media based on establishment of a predetermined payout condition In the gaming machine provided with the device 100 and the payout control device 200), the control means is the number of game media to be paid out after the payout condition is satisfied and before the payout number of game media is paid out. This means that external output means (game control device 100) capable of outputting information on the number of scheduled game medium payouts to the outside is provided. Note that it is also possible to apply this configuration to a slot machine using a game medium as a medal.

  The external output means (game control apparatus 100) is based on storage means (game control apparatus 100) having a game medium storage area for storing the number of game game payouts that have not been output to the outside, and establishment of a payout condition. Addition means (game control device 100) for adding the scheduled game medium payout number corresponding to the established payout condition to the game medium storage area, and the predetermined game medium payout number stored in the game medium storage area has reached a predetermined number Based on this, the transmission means (game control device 100) for transmitting the predetermined number of scheduled game medium payout numbers to the outside, and the predetermined number of scheduled game medium payout numbers transmitted by the transmission means are subtracted from the game medium storage area. Subtracting means (game control device 100).

Here, the transmission timing of the main prize ball signal will be described with reference to FIG. FIG. 100 is a diagram illustrating a transmission timing chart of the main prize ball signal according to the first embodiment.
For example, the game control device 100 outputs one pulse (main prize ball signal) for each predetermined unit number (for example, 10) of game media to be paid out. The output signal of the main prize ball signal rises from “OFF” to “ON” when the value of the output control timer is “48”, and from “ON” to “OFF” when the value of the output control timer is “16”. Until the output control timer value becomes “0”. That is, the output signal of the main prize ball signal is a 192 ms pulse signal composed of an “ON” time of 128 ms and an “OFF” time of 64 ms.

  Note that, unlike the game control device 100, the payout control device 200 outputs one pulse (prize ball signal) for each payout of a predetermined unit number (for example, 10) of game media. Thereby, the gaming machine 10 can make the external device check the match between the game medium payout schedule and the game medium payout result, and can deal with illegal payout.

  In addition, in the winning during the big hit period, when the game medium is delayed due to the ball running out, and the game medium is paid out after the big hit, the external device only has a winning ball signal output by the payout control device 200. It was not possible to determine whether or not the payout was based on a win during the jackpot period. However, the game control device 100 outputs the main prize ball signal so that an external device (for example, a hall computer) can accurately collect (judge) information.

[Start signal editing process]
Next, details of the start port signal editing process (step C89) in the external information editing process described above will be described with reference to FIG. FIG. 101 is a diagram illustrating a flowchart of the start port signal editing process according to the first embodiment. The start port signal editing process is a process commonly performed for each input when there is an input from the start port 1 switch 36a or the start port 2 switch 37a.

  In the start port signal editing process, first, if the start port signal output control timer is not “0”, “−1” is updated (step C111). The minimum value of the start port signal output control timer is set to “0”. Then, it is determined whether or not the value of the start port signal output control timer is “0” (step C112). When the value of the start port signal output control timer is “0” (step C112; Y), it is determined whether or not the number of start port signal outputs is “0” (step C113).

  If the start port signal output count is not “0” (step C113; N), the start port signal output count is updated by “−1” (step C114), and the start port signal output is output to the start port signal output control timer area. The control timer initial value is saved (step C115). The initial value of the start port signal output control timer is obtained by adding a time (for example, 128 ms) of the start state (for example, high level) of the start port signal and a time (for example, 64 ms) of the off state (for example, low level) ( For example, 192 ms). Thereafter, ON data for turning on the start port signal is saved in the external information output data area of the RWM (step C117), and the start port signal editing process is terminated. When the start port signal output count is “0” (step C113; Y), the off data for turning off the start port signal for the external device is saved in the external information output data area of the RWM (step S113). C118), the start port signal editing process is terminated.

  On the other hand, when the value of the start port signal output control timer is not “0” (step C112; N), it is determined whether or not the start port signal output control timer is in the output on period (step C116). Note that the fact that the start port signal output control timer is in the output-on period means that the value of the start port signal output control timer is equal to or longer than a predetermined time (for example, 64 ms). If the start port signal output control timer is in the output on period (step C116; Y), the process proceeds to step C117. If the start port signal output control timer is not in the output on period (step C116; N), the off data for turning off the start port signal for the external device is saved in the external information output data area of the RWM ( Step C118), the start port signal editing process is terminated.

  Next, the variation display mode of the special figure 1 and the common figure will be described with reference to FIGS. As described with reference to FIG. 5, the collective display device 50 includes 32 LEDs from LED_00 to LED_31, and configures the special figure 1 symbol display unit 53 by 8 LEDs from LED_06 to LED_13. The universal symbol display section 55 is composed of four LEDs from LED_24 to LED_27. Accordingly, the number of LEDs in the special symbol display unit 53 is larger than the number of LEDs in the general symbol display unit 55.

  Here, the display mode of the special figure 1 displayed on the special figure 1 symbol display unit 53 will be described with reference to FIG. FIG. 102 is a diagram showing an example of the changing display of the special figure 1 in the state 1 of the first embodiment.

  The special figure 1 includes a lighting pattern and a stop pattern. A lighting pattern is the display mode in the fluctuation | variation of the special figure 1, and is represented by the lighting mode of eight LED from LED_06 to LED_13. The lighting pattern of the special figure 1 in the state 1 is from the lighting pattern 1 to the lighting pattern 8. The stop pattern is a display mode of the fluctuation result of FIG.

  The display mode during fluctuation of the special figure 1 is the update interval every 80 ms in the order of the lighting pattern 1 to the lighting pattern 2, the lighting pattern 3, the lighting pattern 4, the lighting pattern 5, the lighting pattern 6, the lighting pattern 7, and the lighting pattern 8. Transition with. That is, one period of the lighting pattern of the special figure 1 in the state 1 is 640 ms (= 80 ms × 8).

  The LED lighting mode in the lighting pattern 1 is “OFF, OFF, OFF, ON, ON, OFF, OFF, OFF” in the order of LED_06 to LED_13. And the lighting mode of LED in the lighting pattern 2 is “OFF, OFF, ON, OFF, OFF, ON, OFF, OFF” in the order of LED_06 to LED_13. The lighting mode of the LEDs in the lighting pattern 3 is “OFF, ON, OFF, OFF, OFF, OFF, ON, OFF” in the order of LED_06 to LED_13. The lighting mode of the LEDs in the lighting pattern 4 is “ON, OFF, OFF, OFF, OFF, OFF, OFF, ON” in the order of LED_06 to LED_13. The lighting mode of the LED in the lighting pattern 5 is the same as that of the lighting pattern 3. The lighting pattern of the LED in the lighting pattern 6 is the same as that of the lighting pattern 2. The lighting pattern of the LED in the lighting pattern 7 is the same as that of the lighting pattern 1. And as for the lighting mode of LED in the lighting pattern 8, all of LED_06 to LED_13 are "OFF".

  That is, the display mode during fluctuation in FIG. 1 has a lighting mode that overlaps with other display during fluctuation in some of the display during fluctuation. For example, lighting pattern 1 and lighting pattern 7, lighting pattern 2 and lighting pattern 6, lighting pattern 3 and lighting pattern 5 have overlapping lighting modes. On the other hand, the changing display mode of FIG. 1 has a different lighting mode in the changing display which is continuous in time series. For example, the lighting pattern 2 is different in lighting manner from the immediately preceding lighting pattern 1 and is also different in lighting manner from the immediately following lighting pattern 3.

  Such a display mode during fluctuation in FIG. 1 notifies that LED_06 to LED_09 are moving from right to left in the lighting pattern 1 to the lighting pattern 4 so that the lighting LED moves from right to left. . In addition, the display mode during fluctuation of FIG. 1 notifies that LED_06 to LED_09 is moving from left to right in the lighting pattern 4 to the lighting pattern 7 so that the lighting LED moves from left to right. The display mode during fluctuation in FIG. 1 notifies that the LED_10 to LED_13 are moving in the lighting pattern 1 to the lighting pattern 4 so that the LED to be lit moves from left to right. In addition, the display mode during fluctuation in FIG. 1 notifies that LED_06 to LED_09 are in the lighting pattern 4 to the lighting pattern 7 so that the LED to be lit moves from right to left.

  Thereby, the gaming machine 10 can clearly indicate the area of the special figure 1 symbol display section 53 to the player. For example, the special figure 1 symbol display unit 53 displays the stop pattern of the special figure 1 for 600 ms, but it is not easy for the player to grasp the area of the special figure 1 symbol display unit 53 from the stop pattern. However, since the gaming machine 10 clearly indicates to the player the area of the special figure 1 symbol display unit 53 as described above by the changing display mode of the special figure 1, the player displays the changing display of the special figure 1. By observing the mode, it becomes easy to grasp the stop pattern in the area of the special figure 1 symbol display section 53.

  Next, the display mode of the general map displayed on the general symbol display unit 55 will be described with reference to FIG. FIG. 103 is a diagram illustrating an example of a normal change display in the state 1 of the first embodiment.

  The usual figure includes a lighting pattern and a stop pattern. The lighting pattern is a display mode in a usual fluctuation, and is represented by lighting modes of four LEDs from LED_24 to LED_27. There are lighting patterns from lighting pattern 1 to lighting pattern 4. The stop pattern is a display mode of a usual fluctuation result, and there are a plurality (16 at most).

  The display mode during the usual change transitions from the lighting pattern 1 to the lighting pattern 2, the lighting pattern 3, and the lighting pattern 4 in the order of update intervals of 160 ms. That is, one cycle of the usual lighting pattern is 640 ms (= 160 ms × 4).

  The lighting mode of the LED in the lighting pattern 1 is “OFF, OFF, OFF, ON” in the order of LED_24 to LED_27. And the lighting mode of LED in the lighting pattern 2 is "OFF, OFF, ON, OFF" in order of LED_24 to LED_27. And the lighting mode of LED in the lighting pattern 3 is "OFF, ON, OFF, OFF" in order of LED_24 to LED_27. And the lighting mode of LED in the lighting pattern 4 is "ON, OFF, OFF, OFF" in order of LED_24 to LED_27.

  In other words, the display mode during fluctuation in normal mode has a lighting mode in which some of the display during change does not overlap with other display during change. As a matter of course, the display mode in the normal variation has different lighting modes in the continuous display in the time series. For example, the lighting pattern 2 is different in lighting manner from the immediately preceding lighting pattern 1 and is also different in lighting manner from the immediately following lighting pattern 3.

  In this manner, the display state during the fluctuation of the normal map notifies that the fluctuation of the normal map is being performed such that the LED_24 to the LED_27 move from the right to the left in the lighting pattern 1 to the lighting pattern 4.

  Thereby, the gaming machine 10 can clearly indicate the area of the general symbol display section 55 to the player. For example, the regular symbol display unit 55 displays the regular symbol stop pattern for 600 ms, but it is not easy for the player to grasp the area of the regular symbol display unit 55 from the stop pattern. However, since the gaming machine 10 clearly indicates to the player the area of the general symbol display unit 55 by the display mode in which the normal diagram is changing as described above, the player observes the display mode in which the normal diagram is changing. By doing so, it becomes easy to grasp the stop pattern in the area of the general symbol display section 55.

  Next, the coincidence and difference between the changing display of special figure 1 in state 1 and the changing display of ordinary figure will be described with reference to FIG. FIG. 104 is a diagram illustrating a comparative example of the changing display of the special figure 1 and the normal changing display in the state 1 of the first embodiment.

  In the comparative example of the changing display of Special Figure 1 and the normal changing display, LED_06 to LED_13 and LED_24 to LED_27 are arranged in the horizontal direction, and lighting states of the changing LEDs are arranged in the vertical direction in time series. .

  According to this, the during-change display in FIG. 1 can be divided into the first half of LED_06 to LED_09, the second half of LED_06 to LED_09, the first half of LED_10 to LED_13, and the second half of LED_10 to LED_13. These divided special figure 1 fluctuation displays are shown in four ranges surrounded by a one-dot chain line. Among these, the first half of LED_06 to LED_09 is a special figure 1 changing display (part) which can be compared with the normal changing display.

  In addition, while the normal display is changing, the update timing of LED_24 and LED_27 is the same as that of the first half of LED_06 to LED_09, although the update timing is different from that of special figure 1. The display during normal map change is shown in one range surrounded by a two-dot chain line.

  In other words, the normal change display and the special figure 1 change display (partial) have a common change display (specific change display). In other words, the normal display during change is entirely configured by a specific change display, and the special display during change in FIG. 1 is partially configured by a specific change display. With such a configuration, it is easy for the player to compare and compare the normal display during change and the special figure 1 change display (part).

  At this time, the game machine 10 can clearly indicate to the player that each of the game machines 10 has a different design since the update timing differs between the special figure 1 and the usual figure (the special figure 1 is 80 ms and the usual figure is 160 ms). Moreover, since the update period of the special figure 1 and the update period of the usual figure coincide (both 640 ms), the gaming machine 10 has a range of one illumination pattern of the ordinary figure within a range of one illumination pattern of the special figure 1. It can be clearly shown to the player. In this way, the gaming machine 10 can realize the distinction between the special figure 1 and the common figure by changing the number of LEDs and the update interval between the special figure 1 and the common figure.

  Note that the gaming machine 10 not only helps the player understand the progress of the game by clearly indicating the distinction between the special figure 1 and the ordinary figure, but also provides visibility when the player confirms the progress of the game. improves. Further, the gaming machine 10 can make the display mode of the collective display device 50 that tends to be cluttered, and can improve the aesthetics and design of the gaming machine 10. Moreover, since the gaming machine 10 makes the display mode of the collective display device 50 orderly, it reduces fatigue when the player confirms the progress of the game.

Next, the during-fluctuation display of special figure 1 in state 2 will be described with reference to FIG. FIG. 105 is a diagram illustrating an example of the changing display of the special figure 1 in the state 2 of the first embodiment.
The lighting pattern of the special figure 1 in the state 2 is from the lighting pattern 11 to the lighting pattern 18. There are a plurality of stop patterns (up to 256).

  The display mode during the fluctuation of FIG. 1 is an update interval every 60 ms in the order of the lighting pattern 11 to the lighting pattern 12, the lighting pattern 13, the lighting pattern 14, the lighting pattern 15, the lighting pattern 16, the lighting pattern 17, and the lighting pattern 18. Transition with. That is, one period of the lighting pattern of the special figure 1 in the state 2 is 480 ms (= 60 ms × 8).

  The lighting mode of the LEDs in the lighting pattern 11 is “ON, ON, ON, OFF, OFF, ON, ON, ON” in the order of LED_06 to LED_13. The lighting mode of the LEDs in the lighting pattern 12 is “ON, ON, OFF, ON, ON, OFF, ON, ON” in the order of LED_06 to LED_13. The lighting mode of the LEDs in the lighting pattern 13 is “ON, OFF, ON, ON, ON, ON, OFF, ON” in the order of LED_06 to LED_13. The lighting mode of the LEDs in the lighting pattern 14 is “OFF, ON, ON, ON, ON, ON, ON, OFF” in the order of LED_06 to LED_13. The lighting mode of the LED in the lighting pattern 15 is the same as that of the lighting pattern 13. The lighting pattern of the LED in the lighting pattern 16 is the same as that of the lighting pattern 12. The lighting pattern of the LED in the lighting pattern 17 is the same as that of the lighting pattern 11. And as for the lighting mode of LED in the lighting pattern 18, all of LED_06 to LED_13 are "ON".

  In other words, the display mode during fluctuation of special figure 1 in state 2 differs from the display mode during fluctuation of special figure 1 in state 1 in the LED lighting mode and the update timing of the lighting pattern. Thereby, the gaming machine 10 can display the gaming state of the gaming machine 10 with the special figure 1 symbol display unit 53 instead of the state display unit 57 or in addition to the state display unit 57.

  Such a display mode during fluctuation in FIG. 2 is informed that LED_06 to LED_09 are in the lighting pattern 11 to lighting pattern 14 and the LED to be extinguished moves from right to left to notify that the special figure 1 is changing. . In addition, the display mode during fluctuation in FIG. 1 notifies that LED_06 to LED_09 is moving from left to right in the lighting pattern 14 to the lighting pattern 17 and that the LED to be extinguished moves from left to right. The display mode during fluctuation in FIG. 1 notifies that the LED_10 to LED_13 are moving in the lighting pattern 11 to the lighting pattern 14 so that the LED to be turned off moves from left to right. In addition, the display mode during fluctuation of FIG. 1 notifies that the LED_06 to LED_09 is moving from the lighting pattern 14 to the lighting pattern 17 and that the LED to be extinguished moves from right to left.

  Thereby, even in the state 2, the gaming machine 10 can clearly indicate the area of the special figure 1 symbol display unit 53 to the player. For example, the special figure 1 symbol display unit 53 displays the stop pattern of the special figure 1 for 600 ms, but it is not easy for the player to grasp the area of the special figure 1 symbol display unit 53 from the stop pattern. However, since the gaming machine 10 clearly indicates to the player the area of the special figure 1 symbol display unit 53 as described above by the changing display mode of the special figure 1, the player displays the changing display of the special figure 1. By observing the mode, it becomes easy to grasp the stop pattern in the area of the special figure 1 symbol display section 53.

  In the first embodiment, the state of lighting of the changing LED in FIG. 1 and the update timing of the lighting pattern are changed to clearly distinguish between the state 1 and the state 2; The state 1 and the state 2 may be clearly indicated by any one of the lighting mode of the LED inside and the update timing of the lighting pattern.

  Next, the display mode of the general map in the state 2 displayed on the general symbol display unit 55 will be described with reference to FIG. FIG. 106 is a diagram illustrating an example of a normal change display in the state 2 of the first embodiment.

The usual lighting pattern in the state 2 is from the lighting pattern 11 to the lighting pattern 14. There are a plurality of stop patterns (up to 16 patterns).
The display mode in the normal state in the state 2 changes in the order of the lighting pattern 11, the lighting pattern 12, the lighting pattern 13, and the lighting pattern 14 at an update interval of 120 ms. That is, one cycle of the usual lighting pattern is 480 ms (= 120 ms × 4).

  The lighting mode of the LEDs in the lighting pattern 11 is “ON, ON, ON, OFF” in the order of LED_24 to LED_27. And the lighting mode of LED in the lighting pattern 12 is "ON, ON, OFF, ON" in order of LED_24 to LED_27. And the lighting mode of LED in the lighting pattern 13 is "ON, OFF, ON, ON" in order of LED_24 to LED_27. And the lighting mode of LED in the lighting pattern 14 is "OFF, ON, ON, ON" in order of LED_24 to LED_27.

  That is, the display mode in the normal state in the state 2 is different from the display mode in the normal state in the state 1 in the LED lighting mode and the lighting pattern update timing. Thereby, the gaming machine 10 can display the gaming state of the gaming machine 10 on the general symbol display unit 55 instead of the state display unit 57 or in addition to the state display unit 57.

  In this manner, the display mode during the fluctuation of the usual time is notified that the LED_24 to the LED_27 changes from the lighting pattern 11 to the lighting pattern 14 so that the LED to be turned off moves from right to left.

  Thereby, the gaming machine 10 can clearly indicate the area of the general symbol display section 55 to the player. For example, the regular symbol display unit 55 displays the regular symbol stop pattern for 600 ms, but it is not easy for the player to grasp the area of the regular symbol display unit 55 from the stop pattern. However, since the gaming machine 10 clearly indicates to the player the area of the general symbol display unit 55 by the display mode in which the normal diagram is changing as described above, the player observes the display mode in which the normal diagram is changing. By doing so, it becomes easy to grasp the stop pattern in the area of the general symbol display section 55.

  In addition, in 1st Embodiment, although the lighting mode of the LED in the fluctuation of a usual figure and the update timing of a lighting pattern were changed, it showed clearly that the state 1 and the state 2 could be distinguished, The state 1 and the state 2 may be clearly indicated by any one of the lighting state of the LED and the update timing of the lighting pattern.

[Modification of First Embodiment]
Next, the points of coincidence and differences between the changing display of special figure 1 and the changing display of ordinary figure in the modification of the first embodiment will be described with reference to FIG. FIG. 107 is a diagram showing a comparative example of the changing display (modified example) of the special figure 1 of the first embodiment and the normal changing display (modified example).

  Unlike the collective display device 50 of the first embodiment, the collective display device 50 of the modification of the first embodiment forms the special figure 1 symbol display unit 53 with two LEDs, LED_06 and LED_07, and The common symbol display section 55 is composed of one LED. Therefore, also in the modification of the first embodiment, the number of LEDs in the special symbol display unit 53 is larger than the number of LEDs in the general symbol display unit 55.

  In the comparative example of the special display 1 during change (modified example) and the normal display during change (modified example), LED_06, LED_07, and LED_24 are arranged in the horizontal direction, and the lighting state of each changing LED is time-sequentially. Are arranged vertically.

  According to this, the display during variation (modified example) of FIG. 1 can be divided into a display during variation of LED_06 and a display during variation of LED_07. These divided special figure 1 fluctuation displays are shown in two ranges surrounded by a one-dot chain line. Among these, the LED_06 display during change is a special figure 1 change display (part) which can be compared with the normal display during change.

  In addition, the LED_24 display during change is the same as the LED_06 display during change, and the update timing of the display during change is the same (for example, display update during change every 128 ms). The display during normal map change is shown in one range surrounded by a two-dot chain line.

  In other words, the normal change display and the special figure 1 change display (partial) have a common change display (specific change display). In other words, the normal display during change is entirely configured by a specific change display, and the special display during change in FIG. 1 is partially configured by a specific change display. With such a configuration, it is easy for the player to compare and compare the normal display during change and the special figure 1 change display (part). In this way, even when the number of LEDs in Special Figure 1 is two and the number of LEDs in Conventional Figure is one, the normal display during change and the special figure 1 change display (part) Can be used to set a common variable display.

  Note that the gaming machine 10 improves the visibility when the player confirms the progress of the game by setting the display during fluctuation common to the special figure 1 and the common figure. Further, the gaming machine 10 can make the display mode of the collective display device 50 that tends to be cluttered, and can improve the aesthetics and design of the gaming machine 10. Moreover, since the gaming machine 10 makes the display mode of the collective display device 50 orderly, it reduces fatigue when the player confirms the progress of the game.

The gaming machine 10 of the first embodiment described above has the following features in one aspect.
(1) The gaming machine 10 includes a collective display device 50 on the front side. The collective display device 50 includes a special symbol 1 symbol display unit 53 (first variation display game display unit) and a general symbol display unit 55 (second variation display game display unit). The special figure 1 symbol display section 53 has eight patterns (first number) of lighting pattern display (result derivation display) and stop pattern display (result display) of the first special figure variation display game (first variation display game). ) LED (indicator). In addition, the general symbol display unit 55 displays a result derivation display and a result display of the general symbol variation display game (second variation display game), a lighting pattern display (result derivation display), and a stop pattern display (result display). Are displayed by four (second number) LEDs (indicator lamps).

  The combination of the first variation display game and the second variation display game is not limited to the first special figure variation display game and the ordinary variation display game. For example, the combination of the first variation display game and the second variation display game includes a first special diagram variation display game and a second special diagram variation display game, a second special diagram variation display game and a general variation display game, or other It may be a combination of variable display games.

  (2) The first variation display game display unit updates the display manner of the first variation display game result derivation display (display during variation) at a first update interval (for example, 80 ms), and the second variation display The game display unit updates the display mode of the second derivation display game result derivation display at a second update interval (for example, 160 ms) different from the first update interval.

  (3) The first variation display game display unit sequentially updates the third derivation display mode (for example, 8 patterns) of the first derivation display result display of the first variation display game, and the second variation display game display unit The display mode is sequentially updated with a fourth number (for example, four patterns) different from the third number in the second derivation display game result derivation display.

(4) One cycle of the display mode update of the first variation display game is the same as one cycle of the display mode update of the second variation display game.
(5) The result derivation display of the first variation display game and the result derivation display of the second variation display game include a common variation display.

(6) The result derivation display of the first variation display game and the result derivation display of the second variation display game have a relationship in which one of the variation displays includes the other variation display.
[Second Embodiment]
Next, the gaming machine 10 of the second embodiment will be described with reference to FIGS. The gaming machine 10 shown in the second embodiment has two sets of decorative symbols. First, the configuration of the display screen in the display device 41 will be described with reference to FIG. FIG. 108 is a diagram illustrating an example of a variable display screen in the display device according to the second embodiment.

  The fluctuation display screen 600 is the display content of the display device 41. The variable display in-progress screen 600 includes two sets of decorative symbols, a special figure 1 hold number display 603, a special figure 2 hold number display 604, a hold display 605, and a hold digest display 606.

  The two sets of decorative symbols include a large symbol group 601 as a first decorative symbol and a small symbol group 602 as a second decorative symbol. The large symbol group 601 is in charge of game production for the purpose of improving entertainment. Therefore, the large symbol group 601 is displayed in a large size at a substantially central portion of the display device 41. The large symbol group 601 includes a left symbol, a middle symbol, and a right symbol. The left symbol, the middle symbol, and the right symbol in the large symbol group 601 of the variation display screen 600 indicate that the corresponding special diagram variation display game is in the variation display state.

  The small symbol group 602 is in charge of notifying the change display state for the purpose of improving the ease of grasping the game state of the player. Therefore, the small symbol group 602 is displayed in a small size on the periphery of the display device 41 so as to ensure visibility without disturbing the display effect by the large symbol group 601. The small symbol group 602 includes a left symbol, a middle symbol, and a right symbol. The left symbol, the middle symbol, and the right symbol in the small symbol group 602 on the variation display screen 600 indicate that the corresponding special diagram variation display game is in the variation display state.

  In general, the large symbol group 601 is displayed larger than the small symbol group 602, has a high degree of freedom in display position, and its display mode can be greatly changed. On the contrary, the small symbol group 602 is displayed smaller than the large symbol group 601 and has a low degree of freedom in display position (for example, fixed position).

  The special figure 1 hold number display 603 displays the reserved memory number (starting memory number) of the special figure 1 game. The special figure 2 number-of-holds display 604 displays the number of reserved figures stored in the special figure 2 game. Depending on the display mode, the hold display 605 can clearly indicate the number of hold memories of the special figure variation display game and can notify the expectation for the game result for each hold memory. The reserved memory number displayed by the hold display 605 corresponds to the sum of the reserved memory number displayed by the special figure 1 hold number display 603 and the reserved memory number displayed by the special figure 2 hold number display 604. The reserved digest display 606 can indicate that the special figure variable display game is in the variable display state and notify the degree of expectation for the game result according to the display mode.

  The small symbol group 602, the special figure 1 hold number display 603, and the special figure 2 hold number display 604 are positions that do not enter the player's blind spot even by the operation of the board effect device 44 or the game ball rolling on the front side. Is always displayed to the player about the variable display status and the number of reserved memories.

  Further, in the gaming machine 10, the large symbol group 601 and the small symbol group 602 are each configured with a three-digit symbol, but may have any number of digits as long as it includes one or more symbols. In addition, the gaming machine 10 has the same number of symbols in the large symbol group 601 and the small symbol group 602, but the large symbol group 601 and the small symbol group 602 have different numbers of symbols. Also good.

  Further, the gaming machine 10 may change the symbol transparency for the large symbol group 601 during the variable display and the stop display or during the variable display (for example, change the transparency from 0% to 50%). The transparency of the symbol for the small symbol group 602 can be fixed (for example, the transparency is fixed at 0%). Thereby, the gaming machine 10 can ensure the visibility of the small symbol group 602 while ensuring the diversity of display effects for the large symbol group 601, and can easily grasp the game state of the player.

  Even if the gaming machine 10 changes the hue of the symbol for the large symbol group 601 (for example, changes from red to blue) during the variable display and during the stop display, or during the variable display, the small symbol group For 602, the hue of the symbol can be fixed (for example, fixed to red). Further, the gaming machine 10 may change the saturation of the symbol for the large symbol group 601 during the variable display and during the stop display (for example, from 100% saturation to 0%). In addition, the saturation of the symbols for the small symbol group 602 can be fixed (for example, fixed at 100% saturation). Further, the gaming machine 10 may change the lightness of the symbol for the large symbol group 601 during the variable display and during the stop display (for example, from 100% lightness to 10%). For the small symbol group 602, the brightness of the symbol can be fixed (for example, fixed at a lightness of 100%). In addition, the gaming machine 10 can change the size of the symbol for the large symbol group 601 during change display, during stop display, or during change display (for example, change from a standard size to an enlarged (reduced) size). Even if it exists, the magnitude | size of a symbol can be fixed about the small symbol group 602. FIG. Also, the gaming machine 10 may change the symbol display position for the large symbol group 601 during the variable display and the stop display, or during the variable display (for example, from the center of the screen to the upper left of the screen) For the small symbol group 602, the symbol display position can be fixed (for example, fixed at the lower right of the screen). Further, the gaming machine 10 can change the design of the large symbol group 601 during change display, during stop display, or during change display (for example, change from a rectangle to a circle or change from a number to a character). Even if it exists, the design of a symbol can be fixed (for example, it fixes to a number) about the small symbol group 602. Further, even if the gaming machine 10 changes the symbol variation display mode for the large symbol group 601 during the variation display (for example, changes from vertical scroll to horizontal scroll), the game symbol display mode for the small symbol group 602 is changed. Can be fixed (for example, fixed to fluctuation in shaft rotation).

  Also by these, the gaming machine 10 can ensure the visibility of the small symbol group 602 while ensuring the diversity of display effects for the large symbol group 601, and can easily grasp the game state of the player.

  In addition, the gaming machine 10 can change the variation mode during variation display for the large symbol group 601 and the small symbol group 602. For example, the gaming machine 10 can easily distinguish between the large symbol group 601 and the small symbol group 602 when the large symbol group 601 is vertically scrolled. Further, the gaming machine 10 can reduce a sense of discomfort given to the player even when the symbols may be updated asynchronously between the large symbol group 601 and the small symbol group 602.

Next, the symbol arrangement of the small symbol group 602 will be described with reference to FIG. FIG. 109 is a diagram illustrating an example of a symbol arrangement of a small symbol group according to the second embodiment.
The small symbol group 602 is composed of a three-digit symbol of a left symbol, a middle symbol, and a right symbol, and each symbol has seven symbols arranged therein. The symbols to be arranged are represented by numbers corresponding to the respective sequences. For example, the left symbol of the array “1” is a symbol “1”, and the left symbol of the array “2” is a symbol “2”. In addition, the symbols to be arranged are given a predetermined color according to the value of the symbols. For example, the symbols “1” and “5” are green symbols, the symbols “2”, “4”, and “6” are blue symbols, and the numbers “3” The symbol “7” is a red symbol. For example, the symbol group shown in red is a symbol with a relatively high value composed of probability variation symbols, and the symbol group shown in blue is a symbol with a second highest value consisting of short-time symbols. Yes, the symbol group shown in green is a symbol which is composed of normal symbols and has a relatively low value. Note that the small symbol group 602 may have the same color as the symbols arranged.

Next, the symbol arrangement of the large symbol group 601 will be described with reference to FIG. FIG. 110 is a diagram illustrating an example of a symbol arrangement of a large symbol group according to the second embodiment.
The large symbol group 601 is composed of a three-digit symbol of a left symbol, a middle symbol, and a right symbol, and each symbol has seven symbols (standard symbols) arranged therein. The standard symbol is represented by a chamfered square frame and a number in the square frame corresponding to each array. For example, the left symbol of the array “1” is a symbol including a number “1” in a square frame, and the left symbol of the array “2” is a symbol including a numeral “2” in a square frame. The arranged symbols may be given a predetermined color according to the value of the symbols. For example, the symbols “1” and “5” are green symbols, the symbols “2”, “4”, and “6” are blue symbols, and the numbers “3” The symbol “7” is a red symbol.

  Further, the large symbol group 601 can include a dedicated symbol in addition to the standard symbol. In the large symbol group 601, when a symbol array consisting of only standard symbols is a standard time symbol array, a symbol array obtained by adding a dedicated symbol to a standard symbol can be used as a special time symbol array. The large symbol group 601 can switch the standard time symbol arrangement to the special time symbol arrangement when triggered by, for example, a predetermined effect or notification of a predetermined result. Note that the special time symbol array includes one or more dedicated symbols, and the number is not limited to one. Further, the special time symbol arrangement is not limited to the symbol arrangement obtained by adding the dedicated symbols to the standard symbols, and one or more symbols in the standard symbols may be replaced with the dedicated symbols.

  For example, in the large symbol group 601, the special time symbol arrangement may be seven standard symbols and one dedicated symbol, seven standard symbols and two dedicated symbols, or six standard symbols and one dedicated symbol. It is good also as a symbol, and it is good also as seven exclusive symbols instead of all the standard symbols.

  The dedicated symbol is a display mode that can be distinguished from the standard symbol, and is represented by, for example, a chamfered square frame and characters or figures in the square frame. The dedicated symbol includes, for example, “tiger”, “pig”, and “lion” as characters for notifying transition to a predetermined gaming state in the variable display game. At this time, “tiger” reports the transition to tiger mode (for example, latent probability change), “pig” reports the transition to pig (pig) mode (for example, Fuden support), and “lion” is a lion. Informs the transition to the (ladder) mode (for example, probability fluctuation). Note that the dedicated symbol may include, for example, “tiger”, “pig”, and “lion” as characters for notifying a predetermined effect in the variable display game. At this time, “Tiger” foretells the production of characters like tigers (tigers), “Pig” foretells the production of characters like pigs (pigs), and “Reiko” means lions (lions) A notice of the appearance of a character like

  In addition, the dedicated symbol is, for example, “?”, “!”, “!!”, “chance”, “extreme heat”, “ Including “definite”. At this time, “?” Reports the jackpot reliability “1%”, “!” Reports the jackpot reliability “10%”, and “!!” reports the jackpot reliability “20%”. “Chance” reports the jackpot reliability “30%”, “Intense fever” reports the jackpot reliability “90%”, and “Sure” reports the jackpot reliability “100%”. The dedicated symbol includes, for example, “development” and “continuation” as characters for informing the progress in the variable display game. At this time, “Development” reports the progress to super reach, and “Continue” reports the continuation of the pseudo-ream. The dedicated symbol includes, for example, “winning”, “this 5R”, “this 16R”, “short time”, and “probability change” as characters for informing the value of the result (winning) derived from the variable display game. At this time, “win” notifies the hit itself without clearly indicating the magnitude of the value, “this 5R” notifies that it is a hit of 5R round, and “this 16R” indicates that it is a hit of 16R round. Notification is made to notify that “time reduction” is a hit with time reduction (general power support), and “probability change” notifies that it is a hit with probability fluctuation.

  The dedicated symbol includes, for example, “mode A”, “mode B”, and “mode C” as characters for informing the mode change on the display effect. At this time, “mode A” notifies the transition to mode A, “mode B” notifies the transition to mode B, and “mode C” notifies the transition to mode C. In addition, the dedicated symbol includes, for example, “last 10 times” as a character for notifying the number of continuations of a predetermined gaming state such as general power support and probability variation. At this time, “last 10 times” notifies that the remaining number of probability fluctuations is 10 times. In addition, the dedicated symbol includes, for example, “Press!” As characters for notifying game guidance. At this time, “Press!” Notifies the reception timing of the pressing operation of the push button (option setting unit 25).

  Here, the option setting unit 25 described with reference to FIG. 1 will be described again. The option setting unit 25 includes a plurality of systems (for example, eight) of LEDs (push button LEDs), a plurality of systems (for example, eight) of touch sensors, and a push button SW. Each push button LED is a full color LED. The touch sensor can detect a player's touch operation. The push button SW can detect the pressing operation of the option setting unit 25. The selection button switch 25a and the determination button switch 25b are signals detected by a combination of a detection signal from the touch sensor and a detection signal from the push button SW. For example, the state in which the touch sensor detects the touch operation at the left and right positions corresponding to the selection operation and the push button SW detects the pressing operation of the option setting unit 25 corresponds to the ON state of the selection button switch 25a. The state in which the touch sensor detects the touch operation at the center position corresponding to the determination operation and the push button SW detects the pressing operation of the option setting unit 25 corresponds to the ON state of the determination button switch 25b. Hereinafter, the option setting unit 25 may be referred to as a push button or PB (Push Button).

  Next, display effects of the gaming machine 10 according to the second embodiment will be described with reference to FIGS. FIG. 111 is a diagram illustrating an example of an effect flow according to the second embodiment. FIG. 112 is a diagram illustrating an example (part 1) of a screen displayed by the display device according to the second embodiment. FIG. 113 is a diagram illustrating an example (part 2) of a screen displayed by the display device according to the second embodiment. FIG. 114 is a diagram illustrating an example (part 3) of a screen displayed by the display device according to the second embodiment. FIG. 115 is a diagram illustrating an example (part 4) of a screen displayed by the display device of the second embodiment. FIG. 116 is a diagram illustrating an example (No. 5) of a screen displayed by the display device of the second embodiment.

  [Direction Flow F90] The gaming machine 10 stops and displays the symbols before the start of the change in the change display game. A screen 610 shown in FIG. 112 (F90) shows a state where the large symbol group 601 and the small symbol group 602 are stopped and displayed. At this time, the reserved digest display 606 indicates that the special figure variation display game is not in the variation display state by a blank display. When the gaming machine 10 starts the symbol variation, the game machine 10 proceeds to the effect flow F91.

  [Production flow F91] The gaming machine 10 starts variable display. A screen 611 shown in FIG. 112 (F91) indicates that the large symbol group 601 and the small symbol group 602 have started the variable display. At this time, the special figure 2 hold number display 604 displays the special figure 2 game with the stored number reduced by one, and the hold display 605 displays the special figure variable display game with the stored number reduced by one. To do. The reserved digest display 606 indicates that the special figure variation display game is in the variation display state. The gaming machine 10 proceeds to an effect flow F92 when no reach occurs, and proceeds to an effect flow F94 when reach occurs.

  [Production flow F92] The gaming machine 10 temporarily stops displaying the symbols before the change stop. A screen 612 shown in FIG. 112 (F92) shows a state where the large symbol group 601 swings up and down and is temporarily stopped. At this time, the small symbol group 602 shows a state in which it is variably displayed at a uniform speed. Thereby, the gaming machine 10 can clearly indicate that it is not in a state where the change has been stopped yet by the small symbol group 602. The gaming machine 10 proceeds to the production flow F93 when stopping the symbol variation.

  [Production flow F93] The gaming machine 10 stops and displays the symbols. A screen 613 shown in FIG. 112 (F93) shows a state where the large symbol group 601 and the small symbol group 602 stop changing display, and the large symbol group 601 and the small symbol group 602 stop displaying. At this time, the reserved digest display 606 indicates that the special figure variation display game is not in the variation display state by a blank display. Thereby, even if the difference between the temporary stop display and the stop display mode of the large symbol group 601 is ambiguous, the gaming machine 10 can clearly indicate whether or not it is in a variable stop state by the small symbol group 602. That is, the small symbol group 602 has a function as a guidance display for guiding the variable display state of the large symbol group 601.

  It should be noted that the gaming machine 10 can also confirm whether or not it is in a state where the change is stopped by using the collective display device 50 or the like. However, in this case, the gaming machine 10 forces the player to move the line of sight, and there is a possibility that the effect of the effect may be reduced by overlooking the effect display performed by the player on the display device 41. On the other hand, since the gaming machine 10 can display the small symbol group 602 on the same display device 41 as the large symbol group 601, an environment in which the player can concentrate on the effect display performed on the display device 41 can be provided.

  In addition, the gaming machine 10 matches the result derivation mode of the large symbol group 601 and the result derivation mode of the small symbol group 602 as the left symbol “3”, the middle symbol “6”, and the right symbol “4”. The result derivation mode of the large symbol group 601 and the result derivation mode of the small symbol group 602 may be different. For example, the gaming machine 10 sets the result derivation mode of the large symbol group 601 as the left symbol “3”, the middle symbol “6”, and the right symbol “4”, and sets the result derivation mode of the small symbol group 602 as the left symbol “3”, The middle symbol “5” and the right symbol “7” may be used.

  [Production Flow F94] The gaming machine 10 displays a symbol in a reach state. A screen 614 shown in FIG. 113 (F94) shows a reach state in which the left and right symbols of the large symbol group 601 swing up and down to temporarily stop and the middle symbol is changing. At this time, the small symbol group 602 shows a state in which it is variably displayed at a uniform speed. In addition, the screen 614 clearly indicates the occurrence of reach by the guidance display 615. When the gaming machine 10 develops into a battle effect after the occurrence of reach, the game machine 10 proceeds to an effect flow F95.

  [Production Flow F95] The gaming machine 10 displays a battle effect. Screen 616 shown in FIG. 113 (F95) hides large symbol group 601 and displays battle effect guidance display 617 and characters 618, 619. Thereby, the gaming machine 10 guides the player to start a battle effect in which the character 618 and the character 619 compete. At this time, the gaming machine 10 improves the effect of the battle effect by hiding the large symbol group 601. In addition, the gaming machine 10 clearly displays that the small symbol group 602 is variably displayed without depending on the large symbol group 601 by variably displaying the small symbol group 602. The gaming machine 10 proceeds to the effect flow F96 when the result of the battle effect is losing, proceeds to the effect flow F98 when the result of the battle effect is a win, and proceeds to the effect flow F102 when the result of the battle effect is a draw.

  [Production Flow F96] The gaming machine 10 displays the result of losing the battle effect. Screen 620 shown in FIG. 113 (F96) hides large symbol group 601 and displays characters 618, 619, battle effect result guidance display 621, battle display 622, and lines 623, 624. Characters 618, 619, battle effect result guidance display 621, battle display 622, and lines 623, 624 guide the result of losing in battle effect depending on the display mode. At this time, the gaming machine 10 improves the effect of the battle effect by hiding the large symbol group 601. In addition, the gaming machine 10 clearly displays that the small symbol group 602 is variably displayed without depending on the large symbol group 601 by variably displaying the small symbol group 602. For example, the gaming machine 10 can produce a sense of anticipation of the reverse effect with respect to the result of the battle effect by guiding the small symbol group 602 during the variable display. When the gaming machine 10 guides the result lost in the battle effect, the game machine 10 proceeds to the effect flow F97.

  [Production flow F97] The gaming machine 10 displays the fluctuation display result. The screen 625 shown in FIG. 113 (F97) displays the temporary stop display with the large symbol group 601 swinging up and down in a symbol combination manner corresponding to the disengagement, and the small symbol group 602 stopped and displayed in a symbol combination manner corresponding to the disengagement. Indicates the state of Thereby, the gaming machine 10 can indicate that the change display result has been confirmed by the small symbol group 602 while producing the period in which the sense of expectation of re-variation of the large symbol group 601 is maximized. Note that the gaming machine 10 may indicate a state in which the large symbol group 601 and the small symbol group 602 are stopped and displayed as shown in the effect flow F93. Further, the gaming machine 10 may selectively display the stop state shown in the effect flow F97 and the stop state shown in the effect flow F93 (for example, according to the reliability).

Thereafter, the gaming machine 10 may proceed to the effect flow F91 through the effect flow F90, or may proceed to the effect flow F91 without passing through the effect flow F90.
The gaming machine 10 also displays the small symbol group 602 in a uniform manner at a uniform speed while the large symbol group 601 swings up and down and temporarily stops display in a symbol combination manner corresponding to the disengagement in the effect flow F97. Then, the large symbol group 601 and the small symbol group 602 may be stopped and displayed.

  [Direction Flow F98] The gaming machine 10 displays the result of winning the battle effect. Screen 626 shown in FIG. 114 (F98) hides large symbol group 601 and displays characters 618, 619, words 623, 624, battle effect result guidance display 627, and battle display 628. Characters 618, 619, lines 623, 624, battle effect result guidance display 627, and battle display 628 guide the result of winning the battle effect depending on the display mode. At this time, the gaming machine 10 improves the effect of the battle effect by hiding the large symbol group 601. In addition, the gaming machine 10 clearly displays that the small symbol group 602 is variably displayed without depending on the large symbol group 601 by variably displaying the small symbol group 602. When the gaming machine 10 guides the result of winning the battle effect, the game machine 10 proceeds to the effect flow F99.

  [Production flow F99] The gaming machine 10 displays the fluctuation display result. The screen 629 shown in FIG. 114 (F99) swings up and down in a symbol combination manner corresponding to the large symbol group 601 and temporarily stops, and the small symbol group 602 stops and displays in a symbol combination manner corresponding to the winning. Indicates the state of Thereby, the gaming machine 10 can indicate that the change display result has been confirmed by the small symbol group 602 while producing the expectation of the re-variation of the large symbol group 601 in the maximum period. Note that the gaming machine 10 may indicate a state in which the large symbol group 601 and the small symbol group 602 are stopped and displayed as shown in the effect flow F93.

  Further, the gaming machine 10 may not stop the small symbol group 602 while the large symbol group 601 is temporarily stopped. When the small symbol group 602 is not stopped and displayed while the large symbol group 601 is temporarily stopped, the gaming machine 10 proceeds from the effect flow F98 to the effect flow F100.

  [Production flow F100] The gaming machine 10 displays the fluctuation display result. A screen 630 shown in FIG. 114 (F100) shows a state in which the large symbol group 601 swings up and down in a symbol combination manner corresponding to the win and is temporarily stopped. At this time, the small symbol group 602 shows a state in which it is variably displayed at a uniform speed. Thereby, the gaming machine 10 can clearly indicate that it is not in a state where the change has been stopped yet by the small symbol group 602. The gaming machine 10 proceeds to the production flow F101 when the symbol variation is stopped.

  Note that the gaming machine 10 may display the variation of the small symbol group 602 with the symbols aligned after displaying the result of winning the battle effect as shown in the effect flow F98. For example, after displaying the result of winning the battle effect, the gaming machine 10 changes the small symbol group 602 to “1 (left symbol), 1 (middle symbol), 1 (right symbol)”, “2, 2, 2”. , “3, 3, 3”,... Are displayed in a variable pattern combination corresponding to the winning combination. At this time, the gaming machine 10 may improve the visibility by lowering the fluctuation speed than when the fluctuation display is performed at a uniform speed.

  [Production Flow F101] The gaming machine 10 displays a variation display result. A screen 631 shown in FIG. 114 (F101) shows a state in which the large symbol group 601 is not displayed and the small symbol group 602 is stopped and displayed in a symbol combination mode corresponding to the winning combination. The screen 631 displays a variable display result guidance display 632 and a character 633. As a result, the gaming machine 10 determines the variation display result by the small symbol group 602, the variation display result guidance display 632, and the character 633 while producing the period in which the expectation of re-variation of the large symbol group 601 is maximized. You can show that

  Note that the gaming machine 10 may not display the special figure 1 hold number display and the special figure 2 hold number display on the screen 631. In this way, the gaming machine 10 displays the special figure 1 hold number display and the special figure 2 hold number display when the small symbol group 602 is in the variable display, and special features when the small symbol group 602 is in the stop display. The hold number display in FIG. 1 and the special figure 2 hold number display can be hidden. Note that the gaming machine 10 does not display the special figure 1 hold number display and the special figure 2 hold number display when the small symbol group 602 is stopped only when a specific gaming state (for example, a big hit) is derived. It is good.

  [Production flow F102] The gaming machine 10 displays the result of the battle effect. Screen 634 shown in FIG. 115 (F102) hides large symbol group 601 and displays characters 618, 619, words 623, 624, battle effect result guidance display 635, and battle display 636. Characters 618, 619, lines 623, 624, battle effect result guidance display 635, and battle display 636 guide the result of the battle effect drawn according to the display mode. At this time, the gaming machine 10 improves the effect of the battle effect by hiding the large symbol group 601. In addition, the gaming machine 10 clearly displays that the small symbol group 602 is variably displayed without depending on the large symbol group 601 by variably displaying the small symbol group 602. When the gaming machine 10 guides the result of the draw in the battle effect, the game machine 10 proceeds to the effect flow F103.

  [Production Flow F103] The gaming machine 10 displays the temporary stop display mode of the large symbol group 601 including the dedicated symbol 638. A screen 637 shown in FIG. 115 (F103) shows a state in which the large symbol group 601 swings up and down and temporarily stops in a symbol combination mode including the dedicated symbol 638 (the dedicated symbol “tiger”). At this time, the small symbol group 602 shows a state in which it is variably displayed at a uniform speed. Thereby, the gaming machine 10 can guide the progress of the game being variably displayed, the game result, and the like using the dedicated symbol 638. The gaming machine 10 displays the temporary stop display mode of the large symbol group 601 including the dedicated symbol 638, and then proceeds to the effect flow F104.

  [Direction Flow F104] The gaming machine 10 displays the game result guided by the dedicated symbol. A screen 639 shown in FIG. 115 (F104) shows a state in which the large symbol group 601 is hidden and the small symbol group 602 is stopped and displayed in a symbol combination mode corresponding to the tiger mode (for example, latent probability change) entry. . The screen 639 displays a game result guidance display 640 and a mode-specific background display 641. Thereby, the gaming machine 10 produces a change display result by the small symbol group 602, the game result guidance display 640, and the mode-specific background display 641, while producing the expectation of the re-variation of the large symbol group 601 in the maximum period. Can be confirmed.

  Note that the gaming machine 10 may not display the special figure 1 hold number display and the special figure 2 hold number display on the screen 639. Note that the gaming machine 10 does not display the special figure 1 hold number display and the special figure 2 hold number display when the small symbol group 602 is stopped only when deriving a specific gaming state (for example, latent probability change). It is good also as a display.

  In this way, the gaming machine 10 can guide the symbol combination mode of the small symbol group 602 with the dedicated symbol. As a result, the gaming machine 10 may employ a symbol combination that is not easily understood by the player (for example, a symbol combination that is not a three-digit scale) as the symbol combination mode of the small symbol group 602 corresponding to the tiger mode entry. it can. Such a gaming machine 10 does not require an excessively large symbol arrangement of the small symbol group 602 in order to prepare an easily understandable symbol combination. Therefore, the gaming machine 10 can simply configure the symbol arrangement of the small symbol group 602.

  Note that the gaming machine 10 proceeds to the effect flow F103 when guiding the result of the battle effect drawn in the effect flow F102, but may proceed to an option different from the effect flow F103. For example, the gaming machine 10 can proceed to the effect flow F105, the effect flow F106, the effect flow F107, and the effect flow F108 after the effect flow F102.

  [Production flow F105] The gaming machine 10 displays the temporary stop display mode of the large symbol group 601 including the dedicated symbol. A screen 642 shown in FIG. 116 (F105) shows a state where the large symbol group 601 swings up and down in a symbol combination manner including the dedicated symbol 643 and is temporarily stopped. At this time, the small symbol group 602 shows a state in which it is variably displayed at a uniform speed. Thereby, the gaming machine 10 can guide the development reach by “development” indicated by the dedicated symbol 643. The gaming machine 10 displays the temporary stop display mode of the large symbol group 601 including the dedicated symbol, and then proceeds to an effect flow (not shown) corresponding to the development reach.

  [Production Flow F106] The gaming machine 10 displays the temporary stop display mode of the large symbol group 601 including the dedicated symbol. A screen 644 shown in FIG. 116 (F106) shows a state where the large symbol group 601 swings up and down in a symbol combination manner including the dedicated symbol 645 and is temporarily stopped. At this time, the small symbol group 602 shows a state in which it is variably displayed at a uniform speed. As a result, the gaming machine 10 can perform 16 rounds of big hit guidance by “to 16R” indicated by the dedicated symbol 645. The gaming machine 10 displays the temporary stop display mode of the large symbol group 601 including the dedicated symbol, and then proceeds to the effect flow (for example, the effect flow F101) corresponding to the big hit.

  [Production flow F107] The gaming machine 10 displays the temporary stop display mode of the large symbol group 601 including the dedicated symbol. A screen 646 shown in FIG. 116 (F107) shows a state in which the large symbol group 601 swings up and down and temporarily stops in a symbol combination manner including the dedicated symbols 647 and 648. At this time, the small symbol group 602 shows a state in which it is variably displayed at a uniform speed. As a result, the gaming machine 10 can perform guidance with a high degree of reliability by the “super heat” indicated by the dedicated symbol 647. Further, the gaming machine 10 can perform operation guidance of the push button 25 by “press!” Indicated by the dedicated symbol 648. After displaying the temporary stop display mode of the large symbol group 601 including the dedicated symbols, the gaming machine 10 proceeds to an effect flow (not shown) corresponding to the progress of reach.

  [Production flow F108] The gaming machine 10 displays the temporary stop display mode of the large symbol group 601 including the dedicated symbol. A screen 649 shown in FIG. 116 (F108) shows a state where the large symbol group 601 swings up and down in a symbol combination manner including the dedicated symbol 650 and is temporarily stopped. At this time, the small symbol group 602 shows a state in which it is variably displayed at a uniform speed. Thereby, the gaming machine 10 can guide the development reach by “development” indicated by the dedicated symbol 650. The gaming machine 10 displays the temporary stop display mode of the large symbol group 601 including the dedicated symbol, and then proceeds to an effect flow (not shown) corresponding to the development reach.

  In this way, the gaming machine 10 can replace one or more symbols (standard symbols) included in the large symbol group 601 with dedicated symbols. For example, the gaming machine 10 can replace any one of the left symbol, the middle symbol, and the right symbol included in the large symbol group 601 with a dedicated symbol. Further, the gaming machine 10 can replace any two of the left symbol, middle symbol, and right symbol included in the large symbol group 601 with a dedicated symbol. In addition, the gaming machine 10 can replace all of the left symbol, middle symbol, and right symbol included in the large symbol group 601 with dedicated symbols. The gaming machine 10 can provide more detailed game guidance by including two or more dedicated symbols in the large symbol group 601.

  In addition, the gaming machine 10 replaces the left symbol and the middle symbol included in the large symbol group 601 with one dedicated symbol, replaces the middle symbol and the right symbol with one dedicated symbol, the left symbol, the middle symbol, and the right symbol. A symbol can be replaced with one dedicated symbol.

  Next, the symbol replacement timing in the variable display of the small symbol group 602 will be described with reference to FIG. FIG. 117 is a diagram illustrating an example of a timing chart showing symbol replacement timings in the small symbol group variation display according to the second embodiment.

  The game control device 100 performs the fluctuation display of the special figure 1 and the special figure 2 on the collective display device 50, and changes to the effect control apparatus 300 in synchronization with the fluctuation display of the special figure 1 and the special figure 2 performed on the collective display device 50. Send display commands. The effect control device 300 receives a command related to variation display from the game control device 100, and performs variation display of the large symbol group 601 and the small symbol group 602.

  The timing chart TC1 shows a state in which the game control device 100 displays the fluctuation of the time T1 from the timing t11 to the timing t16 and displays the stop of the time T5 from the timing t16 to the timing t17 with respect to the special figure 1 or FIG.

  In the timing chart TC2, the effect control device 300 performs the synchronous variation display of the time T2 from the timing t11 to the timing t12, the asynchronous variation display of the time T3 from the timing t12 to the timing t16, and the timing t16 to the timing t17. A state in which stop display at time T5 is performed is shown.

  In the timing chart TC3, the effect control device 300 performs the synchronous variation display of the time T2 from the timing t11 to the timing t12 for the large symbol group 601 and performs the asynchronous variation display of the time T3 from the timing t12 to the timing t16, and from the timing t16 to the timing t17. A state in which stop display at time T5 is performed is shown. Asynchronous variation display of the large symbol group 601 is different in, for example, the variation display mode (including the variation speed) from timing t12 to timing t13, from timing t13 to timing t14, and from timing t14 to timing t15, so as to improve the display effect. ing. Asynchronous fluctuation display of the large symbol group 601 performs temporary stop display at time T4 from timing t15 to timing t16 to improve the expectation of the stop symbol.

  Note that the synchronous variation display of the small symbol group 602 and the large symbol group 601 is a period in which the small symbol group 602 and the large symbol group 601 perform variation display in synchronization. The fact that the small symbol group 602 and the large symbol group 601 perform the variable display in synchronism is a variable display having a correspondence relationship between the symbol displayed by the small symbol group 602 and the symbol displayed by the large symbol group 601. . In addition, the fluctuation display performed in synchronization between the small symbol group 602 and the large symbol group 601 has the same fluctuation speed.

  The asynchronous variation display of the small symbol group 602 and the large symbol group 601 is a period in which the small symbol group 602 and the large symbol group 601 perform variation display without being synchronized. The fact that the small symbol group 602 and the large symbol group 601 perform the variable display without being synchronized means that the small symbol group 602 has a variable display that does not correspond to the symbol displayed by the small symbol group 602 and the symbol displayed by the large symbol group 601. is there. Moreover, the fluctuation display performed without the small symbol group 602 and the large symbol group 601 being synchronized does not necessarily match the respective fluctuation speeds.

  When the effect control device 300 switches the small symbol group 602 and the large symbol group 601 from synchronous variation display to asynchronous variation display, each symbol is replaced at timing t12, for example. Thereby, the gaming machine 10 reduces a sense of incongruity due to a difference in display mode between the small symbol group 602 and the large symbol group 601 at the start of variation, the degree of freedom of display effect of the large symbol group 601 during variation display, and the small symbol group. The ease of grasping the game state of the group 602 is improved. In addition, the effect control device 300 can prevent the variable display from being continued while maintaining the symbol combination that the small symbol group 602 reaches or the symbol combination that becomes a big hit. In addition, the effect control device 300 can perform a variable display according to the variation pattern or the stop symbol for the large symbol group 601.

  In addition, when the small symbol group 602 is stopped and displayed, the effect control device 300 replaces each symbol at timing t16, for example. Thereby, the production control device 300 can simplify the variation control (for example, uniform variation) during the variation display of the small symbol group 602.

  The production control device 300 can set the timing at which the stop symbol command is received from the game control device 100 as the timing t11. Since the game control device 100 transmits a stop symbol command, a variation pattern command, and a hold command as a series of commands, the effect control device 300 may use the timing at which the variation pattern command or the hold command is received as the timing t11.

  In addition, since the game control device 100 transmits a stop symbol command, a variation pattern command, and a hold command as a series of commands, the presentation control device 300 uses the timing at which a part of the series of commands is received as timing t11. Also good. For example, the production control device 300 can set the timing at which the stop symbol command and the variation pattern command are received as the timing t11.

  In addition, the production control device 300 can set the timing at which the stop command is received from the game control device 100 as the timing t16. Further, the effect control device 300 may set the timing specified from the variation pattern command as the timing t16.

  Next, the stop display timing of the small symbol group 602 and the temporary stop display timing of the large symbol group 601 will be described with reference to FIG. FIG. 118 is a diagram illustrating an example of a timing chart illustrating a temporary stop timing in the large symbol group variation display according to the second embodiment.

  The stop display timing of the small symbol group 602 shown in the timing chart TC2 is as shown in FIG. Temporary stop display timings of the large symbol group 601 corresponding to the stop display timings of the small symbol group 602 are shown from the timing chart TC31 to the timing chart TC35. The temporary stop display timing of the large symbol group 601 shown by the timing chart TC31 is as shown in FIG.

  The timing chart TC31 shows a state where the large symbol group 601 is temporarily stopped from the timing t15 before the small symbol group 602 is stopped and displayed, and is stopped and displayed at the timing t16 which is the stop display timing of the small symbol group 602. The timing chart TC31 is an example of a display mode in which the player can easily understand the game state.

  The timing chart TC32 indicates that the large symbol group 601 displays a temporary stop from timing t15, and the large symbol group 601 is not displayed at timing t15a before the stop display timing of the small symbol group 602. Further, the timing chart TC32 indicates that, for example, the variable display result guidance display as shown in the effect flow F101 is performed from the timing t15a to the timing t17 when the small symbol group 602 performs the stop display. The timing chart TC32 is an example of variable display that is performed without clarifying the correspondence between the stop symbols of the small symbol group 602 and the large symbol group 601.

  The timing chart TC33 indicates that the large symbol group 601 is temporarily stopped from the timing t15, and the large symbol group 601 is not displayed at the timing t15a before the stop display timing of the small symbol group 602. The timing chart TC32 indicates that the large symbol group 601 is not displayed until the timing t17 when the small symbol group 602 performs stop display. The timing chart TC33 is an example of variable display that is performed without clarifying the correspondence between the stop symbols of the small symbol group 602 and the large symbol group 601.

  The timing chart TC34 indicates that the large symbol group 601 continues to display the temporary stop display until the timing t17 when the large symbol group 601 performs temporary stop display and the small symbol group 602 performs stop display from timing t15. The timing chart TC34 is an example of a change display that increases the expectation of re-change of the stop symbol of the large symbol group 601.

  The timing chart TC35 indicates that the large symbol group 601 displays a temporary stop from timing t15, and the large symbol group 601 is stopped and displayed at a timing t15a before the stop display timing of the small symbol group 602. The timing chart TC35 indicates that the stop display of the large symbol group 601 is continued until the timing t17 when the small symbol group 602 performs stop display. The timing chart TC35 is an example of a variable display that is performed by clarifying the correspondence between the stopped symbols of the small symbol group 602 and the large symbol group 601.

  In this way, the effect control device 300 can provide various modes for the temporary stop timing in the large symbol group variation display. In addition, the effect control device 300 can select one of a plurality of temporary stop timing modes according to, for example, the variation display result and the reliability of the variation display result.

  Next, the replacement symbol (first replacement symbol) of the small symbol group 602 to be replaced at timing t12 will be described with reference to FIG. FIG. 119 is a diagram illustrating an example of a first replacement symbol of the small symbol group according to the second embodiment.

  The effect control device 300 replaces the small symbol group 602 with the first replacement symbol at timing t12. The first replacement symbol is set in advance, for example, one pattern is prepared. Pattern 1 is a symbol combination in which the left symbol is “1”, the middle symbol is “2”, and the right symbol is “3”, which does not form a reach or a big hit. Also, the left symbol “1”, the middle symbol “2”, and the right symbol “3” are different in the color of the symbol, and one of the symbol combinations that can easily recognize that no reach or big hit is formed. It is. Thereby, the production control device 300 prevents the small symbol group 602 during the uniform variation display from appearing like a full rotation reach and giving a misunderstanding.

Although one pattern is prepared for the first replacement symbol, two or more patterns may be provided and selectively replaced.
Further, the production control device 300 may use the first replacement symbol as the final stop symbol. At this time, in order to prevent the small symbol group 602 in the uniform variation display from appearing like a full rotation reach and giving a misunderstanding, the effect control device 300 has a special result (for example, latent probability change, small hit, The first replacement symbol may be used as the final stop symbol except in the case of deriving a big hit. Thereby, the gaming machine 10 can reduce the processing load on the effect control device 300. In addition, the gaming machine 10 can make it possible to predict the final stop symbol by the player gaining gaming experience.

  Next, the replacement symbol (second replacement symbol) of the small symbol group 602 to be replaced at timing t16 will be described with reference to FIG. FIG. 120 is a diagram illustrating an example of a second replacement symbol of the small symbol group according to the second embodiment.

  The production control device 300 replaces the small symbol group 602 with the second replacement symbol at timing t16. The second replacement symbol is set in advance, for example, a plurality of patterns are prepared. Pattern 1 is a symbol combination corresponding to an outage, with the left symbol being “1”, the middle symbol being “2”, and the right symbol being “3”. Patterns 2 to 8 are all symbol combinations corresponding to jackpots, with the left symbol, the middle symbol, and the right symbol forming a slotted pattern. The jackpot corresponding to the symbol combinations of pattern 2 to pattern 8 is a jackpot having a different value depending on each symbol. The pattern 9 is a symbol combination corresponding to the latent probability change, with the left symbol being “1”, the middle symbol being “1”, and the right symbol being “2”.

  In the second replacement symbol, the symbol combination corresponding to the deviation is one pattern, but a plurality of patterns may be provided. Further, the second replacement symbol may be a stop symbol received from the game control device 100 by the effect control device 300, or selected according to the stop symbol received by the effect control device 300 from the game control device 100. It may be a thing.

Next, a modified example of the symbol arrangement of the small symbol group 602 will be described with reference to FIG. FIG. 121 is a diagram illustrating an example of a symbol arrangement of a small symbol group according to a modification of the second embodiment.
The effect control device 300 can change the small symbol group 602 into an irregular symbol arrangement instead of replacing the small symbol group 602 with the first replacement symbol at timing t12.

  The irregular symbol arrangement of the small symbol group 602 is different for the left symbol, the middle symbol, and the right symbol. In the symbol arrangement of the left symbol, the numbers are arranged in the forward direction in the order of arrangement, the symbol arrangement in the middle symbol is arranged in the reverse direction in the order of arrangement, and the symbol arrangement of the right symbol is arranged in the order in which the numbers are randomly set in advance in the arrangement order.

  As a result, the effect control device 300 gives the misunderstanding that the small symbol group 602 in the uniform variation display looks like full rotation reach without replacing the small symbol group 602 with the first replacement symbol at the timing t12. This can be prevented.

  It should be noted that the production control device 300 may change in the reverse direction (return fluctuation) and then change in the forward direction (forward fluctuation) once the large symbol group 601 starts to change. In such a case, the effect control apparatus 300 may replace the symbol displayed by the small symbol group 602 with the previous symbol corresponding to the return variation of the large symbol group 601. For example, when the large symbol group 601 displays “1 (left symbol), 2 (middle symbol), 3 (right symbol)”, the effect control device 300 displays one symbol at the start of variation of the large symbol group 601. After changing back by the minute and displaying “7, 1, 2”, the order changes like “1, 2, 3”, “2, 3, 4”,. At this time, the effect control apparatus 300 synchronizes the fluctuation display of the small symbol group 602 with the fluctuation display of the large symbol group 601 to change from “1, 2, 3” to “7, 3, 6”, “1, 2, 2, 3 ", then forwards like" 2,1,7 ",. Note that “7, 3, 6” in the small symbol group 602 is in the “−1” direction in the symbol arrangement with respect to “1, 2, 3” in the small symbol group 602, and “2,” in the small symbol group 602. “1, 7” is the “+1” direction in the symbol arrangement with respect to “1, 2, 3” of the small symbol group 602 (see FIG. 121). According to this, even if the gaming machine 10 displays the large symbol group 601 and the small symbol group 602 in synchronization, it can be difficult to sense that the player is displaying in synchronization. .

  In addition, when the variation of the large symbol group 601 is less than one symbol, the effect control device 300 displays the small symbol group 602 by rounding it up to the variation of one symbol even if it is an offset variation such as a half symbol. May be. According to this, the production control device 300 can display-control the small symbol group 602 in a concise manner while performing smooth variation display on the large symbol group 601.

  Next, switching of the symbol display mode of the large symbol group 601 will be described with reference to FIGS. 122 and 123. First, a display mode of the large symbol group 601 different from the display mode of the large symbol group 601 shown in FIG. 110 will be described with reference to FIG. FIG. 122 is a diagram illustrating an example of a display mode of a large symbol group according to the second embodiment.

  The large symbol group 601 can switch the display mode of the large symbol group according to the mode and the gaming state. For example, when the gaming machine 10 sets the display mode of the large symbol group 601 shown in FIG. 110 as the display mode in the first state (for example, the normal state, the standard effect mode, etc.), the display of the large symbol group 601 shown in FIG. The mode can be the display mode in the second state (for example, the probability variation state, the special effect mode, etc.).

  In the second gaming state, the gaming machine 10 sets the standard symbol to a display mode that imitates a mahjong tile. Further, the gaming machine 10 makes the dedicated symbol different from the first gaming state in the second gaming state. Further, the gaming machine 10 may increase or decrease the number of dedicated symbols in the second gaming state as compared with the first gaming state. For example, the gaming machine 10 has the dedicated symbol “pig” in the first gaming state, but does not have the dedicated symbol “pig” in the second gaming state.

  Next, switching of the display mode of the symbols of the large symbol group 601 by state will be described with reference to FIG. FIG. 123 is a diagram illustrating an example of switching the display mode of the large symbol group for each state according to the second embodiment.

  (1) The symbol pattern by mode indicates a pattern switching pattern by mode. When there are “mode A”, “mode B”, and “mode C” as display effect modes, the small symbol group 602 is “pattern A” in all of “mode A”, “mode B”, and “mode C”. Fixed. On the other hand, the large symbol group 601 is “pattern A1” in “mode A”, “pattern A2” in “mode B”, and “pattern A3” in “mode C”. For example, “Pattern A1” is a display mode of the large symbol group 601 shown in FIG. 110, “Pattern A2” is a display mode of the large symbol group 601 shown in FIG. 122, and “Pattern A3” is This is a display mode not shown.

  Thus, the gaming machine 10 improves the display effect by switching the display mode of the large symbol group 601 in accordance with the mode switching. Further, the gaming machine 10 can make the player easily grasp the progress of the game by fixing the display mode of the small symbol group 602 regardless of the mode switching.

  (2) The game state-specific symbol pattern indicates a symbol switching pattern for each gaming state. When there are “normal”, “latent probability variation”, and “non-latency probability variation” as the gaming state, the small symbol group 602 is fixed to “pattern S” in all of “normal”, “latency probability variation”, and “non-latency probability variation”. Is done. On the other hand, the large symbol group 601 is “pattern B1” in “normal”, “pattern B2” in “latency probability variation”, and “pattern B3” in “non-latency probability variation”.

  Thus, the gaming machine 10 improves the display effect by switching the display mode of the large symbol group 601 according to the switching of the gaming state. In addition, the gaming machine 10 can make the player easily grasp the progress of the game by fixing the display mode of the small symbol group 602 regardless of the switching of the gaming state.

  Note that the large symbol group 601 shown in FIG. 110 and FIG. 122 has a plurality of dedicated symbols, but these dedicated symbols may be grouped to switch available groups according to the state. The grouping of dedicated symbols and the switching of groups by state will be described with reference to FIG. FIG. 124 is a diagram illustrating an example of switching the dedicated symbol group of the large symbol group according to the state of the second embodiment.

  (1) The mode-specific symbol group indicates a switching pattern of the mode-specific symbol group. When there are “mode A”, “mode B”, and “mode C” as the display effect modes, the gaming machine 10 adds the dedicated symbols selected from the dedicated symbol groups corresponding to each display effect mode to the large symbol group 601. Can be used. The dedicated symbol that can be used for the large symbol group 601 is a dedicated symbol belonging to “group A1” in “mode A”, a dedicated symbol belonging to “group A2” in “mode B”, and “mode C” This is a dedicated symbol belonging to “Group A3”. For example, when the dedicated symbols “tiger”, “pig”, and “lion” among the dedicated symbols shown in FIG. 110 belong to “group A1” and do not belong to “group A2” and “group A3”, the dedicated symbol “tiger” ”,“ Pig ”, and“ lion ”can appear in“ mode A ”and cannot appear in“ mode B ”and“ mode C ”. Thereby, the gaming machine 10 can diversify the game performance for each display effect mode, and can further improve the effect in each display effect mode.

  (2) The dedicated symbol group for each gaming state indicates a switching pattern of the dedicated symbol group for each gaming state. When there are “normal”, “latency probability variation”, and “non-latency probability variation” as the gaming state, the gaming machine 10 uses a dedicated symbol selected from among the dedicated symbol groups corresponding to each gaming state for the large symbol group 601. Can do. The dedicated symbol that can be used for the large symbol group 601 is a dedicated symbol belonging to “Group B1” in “normal”, a dedicated symbol belonging to “Group B2” in “latency probability variation”, and “non-latency probability variation”. This is a dedicated symbol belonging to “Group B3”. As a result, the gaming machine 10 can diversify the game characteristics for each gaming state, and can further improve the effect in each gaming state.

  (3) The dedicated symbol group for each variation process indicates a switching pattern of the dedicated symbol group for each variation process. When there are “normal fluctuation (before reach occurrence)”, “reach (before development reach occurrence)”, and “development reach” as the fluctuation process, the gaming machine 10 selects from the dedicated symbol group corresponding to each fluctuation process. A dedicated symbol can be used for the large symbol group 601. The dedicated symbol that can be used for the large symbol group 601 is a dedicated symbol belonging to “Group C1” in “Normal Variation”, a dedicated symbol belonging to “Group C2” in “Reach”, and “ It is a dedicated symbol belonging to “Group C3”. As a result, the gaming machine 10 can diversify the game performance for each variation process, and can further improve the effect in each variation process.

  Next, as a modified example of the second embodiment, a gaming machine 10 provided with a small symbol group corresponding to each of FIG. 1 and FIG. 2 will be described with reference to FIG. FIG. 125 is a diagram illustrating an example (part 1) of a variable display screen in the display device according to the modification of the second embodiment.

  The variable display in-progress screen 651 is the display content of the display device 41. The variable display in-progress screen 651 includes three sets of decorative symbols, special figure 1 hold number display 653, special figure 2 hold number display 655, hold display 656, and hold digest display 657.

  The three sets of decorative symbols include a large symbol group 601 as a first decorative symbol, a special symbol 1 small symbol group 652 as a second decorative symbol, and a special symbol 2 small symbol group 654 as a third decorative symbol. The large symbol group 601 is in charge of game production for the purpose of improving entertainment. Therefore, the large symbol group 601 is displayed in a large size at a substantially central portion of the display device 41. The large symbol group 601 includes a left symbol, a middle symbol, and a right symbol. The left symbol, the middle symbol, and the right symbol in the large symbol group 601 of the variation display screen 600 indicate that the corresponding special diagram variation display game is in the variation display state.

  The special figure 1 small symbol group 652 is in charge of notifying the fluctuation display state of the special figure 1 for the purpose of improving the ease of grasping the game state of the player. The special figure 2 small symbol group 654 is in charge of notifying the fluctuation display state of the special figure 2 for the purpose of improving the ease of grasping the game state of the player. The special figure 1 small symbol group 652 and the special figure 2 small symbol group 654 are displayed small on the periphery of the display device 41 so as to ensure visibility without disturbing the display effect by the large symbol group 601. Special figure 1 small symbol group 652 and special figure 2 small symbol group 654 each include a left symbol, a middle symbol, and a right symbol. The left symbol, the middle symbol, and the right symbol in the special symbol 1 small symbol group 652 on the variable display middle screen 651 indicate that the corresponding special symbol variable display game is in the variable display state. The left symbol, middle symbol, and right symbol in the special symbol 2 small symbol group 654 on the variable display in-progress screen 651 indicate that the corresponding special symbol variable display game is in the stopped display state.

  The special figure 1 hold number display 653 displays the hold memory number (starting memory number) of the special figure 1 game. The special figure 1 reservation number display 653 is displayed in proximity to the special figure 1 small symbol group 652. The special figure 2 hold number display 655 displays the hold storage number of the special figure 2 game. The special figure 2 reservation number display 655 is displayed in proximity to the special figure 2 small symbol group 654.

  According to the display mode, the hold display 656 can clearly indicate the hold memory number of the special figure variation display game, and can notify the expectation for the game result for each hold memory. The reserved digest display 657 indicates that the special figure variable display game is in the variable display state and can notify the degree of expectation for the game result according to the display mode.

  Thereby, the gaming machine 10 can distinguish between the special figure 1 game and the special figure 2 game and indicate that the special figure fluctuation display game is in the fluctuation display state. The effect control device 300 does not necessarily need to arrange the special figure 1 small symbol group 652 and the special figure 2 small symbol group 654 at a position that does not interfere with the board effect device 44. The effect control device 300 allows the interference between the special symbol 2 small symbol group 654 and the board effect device 44 when the special figure 1 game is in the variable display state, and special effects when the special figure 2 game is in the variable display state. 1 may allow interference between the small symbol group 652 and the board effect device 44. In other words, the production control device 300 can vary the control pattern of the board production device 44 depending on whether the special figure game in the variable display state is the special figure 1 or the special figure 2. Thereby, the gaming machine 10 restricts the board production device 44 based on the interference between the special figure 1 small symbol group 652 and the special figure 2 small symbol group 654 while clearly indicating the fluctuation display state of the special figure fluctuation display game. Can be reduced.

  Next, as a modification of the second embodiment, a gaming machine 10 that changes the display position of a small symbol group will be described with reference to FIG. FIG. 126 is a diagram illustrating an example (part 2) of the variable display screen in the display device according to the modification of the second embodiment.

  The variable display in-progress screen 658 is the display content of the display device 41. The variable display in-progress screen 658 includes two sets of decorative symbols, a special figure 1 hold number display 660, a special figure 2 hold number display 661, a hold display 656, and a hold digest display 657.

  The two sets of decorative symbols include a large symbol group 601 as a first decorative symbol and a small symbol group 659 as a second decorative symbol. The large symbol group 601 is in charge of game production for the purpose of improving entertainment. Therefore, the large symbol group 601 is displayed in a large size at a substantially central portion of the display device 41. The large symbol group 601 includes a left symbol, a middle symbol, and a right symbol. The left symbol, the middle symbol, and the right symbol in the large symbol group 601 of the variation display screen 600 indicate that the corresponding special diagram variation display game is in the variation display state.

  The small symbol group 659 is in charge of notifying of the fluctuation display state of the special figure for the purpose of improving the ease of grasping the game state of the player. The small symbol group 659 is displayed small on the periphery of the display device 41 so as to ensure visibility without disturbing the display effect by the large symbol group 601. The small symbol group 659 includes a left symbol, a middle symbol, and a right symbol, respectively. The left symbol, the middle symbol, and the right symbol in the small symbol group 659 on the variation display middle screen 658 all indicate that the corresponding special diagram variation display game is in the variation display state.

  The production control device 300 does not necessarily need to arrange the small symbol group 659 at a position where it does not interfere with the board production device 44. For example, when the board effect device 44c advances from the left side in front of the display device 41, the effect control device 300 displays the small symbol group 659, the special figure 1 hold number display 660, and the special figure 2 hold number display 661 on the right side. Move to. Thereby, the gaming machine 10 can clearly show the fluctuation display state of the special figure fluctuation display game while reducing the restrictions on the board effect device 44. Further, the gaming machine 10 can clearly display the display states of the special figure 1 hold number display 660 and the special figure 2 hold number display 661 while reducing the restrictions on the board effect device 44.

  The production control device 300 may display the small symbol group 659 by moving even if the board production device 44 does not operate due to a failure or the like. Further, the effect control device 300 may not move and display the small symbol group 659 when the small symbol group 659 and the board effect device 44 do not interfere with each other even when the board effect device 44 operates. According to this, the gaming machine 10 can move to a position where the small symbol group 659 can be viewed well. In addition, the gaming machine 10 can give an advance guidance on the operation of the board effect device 44 according to the movement display mode of the small symbol group 659. That is, the gaming machine 10 can notify that the board effect device 44 operates to the position before the movement of the small symbol group 659 by moving and displaying the small symbol group 659.

  Further, the effect control device 300 is not limited to the operation of the board effect device 44, and the small symbol group 659 may be moved and displayed in a predetermined game state or display state. For example, the effect control device 300 can move the small symbol group 659 to a position where the small symbol group 659 can be visually recognized when there is a possibility that the visibility of the small symbol group 659 may be impaired by a predetermined effect. For example, the effect control device 300 may display the small symbol group 659 when the visibility of the small symbol group 659 may be impaired due to the display content of the display device 41, the lighting mode of the decoration device around the display device 41, or the like. Move to a position where it can be seen well. In addition, the gaming machine 10 can give a notice of a predetermined effect according to the movement display mode of the small symbol group 659. The predetermined effects here include effects in a predetermined gaming state and effects in a predetermined mode.

  The effect control device 300 may move the small symbol group 659 continuously or discretely. Moreover, although the case where the small symbol group 659 is moved and displayed has been described, the effect control apparatus 300 can also move and display the special figure 1 hold number display and the special figure 2 hold number display. Further, the production control device 300 can move and display the special figure 1 hold number display and the special figure 2 hold number display together with the small symbol group 659.

  Next, as a modified example of the second embodiment, a gaming machine 10 that clearly indicates which of the special figure 1 and the special figure 2 is displayed by the display mode of the small symbol group will be described with reference to FIGS. 127 to 129. explain. FIG. 127 is a diagram illustrating an example (part 1) of a variation display mode of a small symbol group according to a modification of the second embodiment. FIG. 128 is a diagram illustrating an example (part 2) of the variation display mode of the small symbol group according to the modification of the second embodiment. FIG. 129 is a diagram illustrating an example (No. 3) of a variation display mode of the small symbol group of the modification example of the second embodiment.

  The small symbol group 662 shown in FIG. 127 (1) displays the same background (for example, the background color “white”) as the background of the special symbol 1 holding number display 663, whereby the special symbol being variably displayed in the small symbol group 662 is displayed. Clarify that the game is Special Figure 1. At this time, the background (for example, background color “black”) of the special figure 2 reservation number display 664 is different from the background of the small symbol group 662 and the background of the special figure 1 reservation number display 663.

  The small symbol group 662 shown in FIG. 127 (2) displays the same background (for example, the background color “black”) as the background of the special symbol 2 reservation number display 664, so that the special symbol being variably displayed in the small symbol group 662 is displayed. Clarify that the game is Special Figure 2. At this time, the background (for example, the background color “white”) of the special figure 1 reservation number display 663 is different from the background of the small symbol group 662 and the background of the special figure 2 reservation number display 664.

Thereby, the gaming machine 10 can distinguish between the special figure 1 game and the special figure 2 game and indicate that the special figure fluctuation display game is in the fluctuation display state.
The small symbol group 665 shown in FIG. 128 (1) displays the background (for example, the background color “white”) shared with the special symbol 1 holding number display 666, so that the special symbol game variably displayed in the small symbol group 665 is displayed. Is clearly shown in Figure 1. At this time, the special figure 2 reservation number display 667 does not share the background with the small symbol group 665 and the special figure 1 reservation number display 666.

  Note that the background of the small symbol group 665 and the background of the special figure 1 reservation number display 666 are not necessarily integrated, and may be separated if they have the same display mode. Also, the background of the small symbol group 665 and the background of the special figure 1 hold number display 666 do not have to have the same display mode, and the special figure 1 game and the special figure 2 game can be distinguished. Some display modes may be the same.

  The small symbol group 665 shown in FIG. 128 (2) displays the background (for example, the background color “white”) shared with the special symbol 2 holding number display 667, so that the special symbol game variably displayed in the small symbol group 665 is displayed. Is clearly shown as Special Figure 2. At this time, the special figure 1 reservation number display 666 does not share the background with the small symbol group 665 and the special figure 2 reservation number display 667.

  Note that the background of the small symbol group 665 and the background of the special figure 2 reservation number display 667 are not necessarily integrated, and may be separated if they have the same display mode. Further, the background of the small symbol group 665 and the background of the special figure 2 reservation number display 667 do not have to be the same in all display modes, and if the special figure 1 game and the special figure 2 game can be distinguished. Some display modes may be the same.

Thereby, the gaming machine 10 can distinguish between the special figure 1 game and the special figure 2 game and indicate that the special figure fluctuation display game is in the fluctuation display state.
The small symbol group 668 shown in FIG. 129 (1) is a special symbol game that is variably displayed in the small symbol group 668 by changing the symbol display to Arabic numerals in the same manner as the reserved number display in the special symbol 1 reserved number display 669. This is clearly shown in FIG. At this time, the special figure 2 hold number display 670 sets the hold number display to Chinese numerals.

  The small symbol group 668 shown in FIG. 129 (2) is a special symbol game that is variably displayed in the small symbol group 668 by changing the symbol display to a Chinese numeral in the same manner as the reserved number display in the special symbol 2 reserved number display 670. This is clearly shown in FIG. At this time, the special figure 1 hold number display 669 uses the Arabic number as the hold number display.

Thereby, the gaming machine 10 can distinguish between the special figure 1 game and the special figure 2 game and indicate that the special figure fluctuation display game is in the fluctuation display state.
Next, as a modified example of the second embodiment, a gaming machine 10 that clearly shows a variable display state by a part of symbols constituting a small symbol group will be described with reference to FIG. FIG. 130 is a diagram illustrating an example (part 4) of a variation display mode of a small symbol group according to a modification of the second embodiment.

  A small symbol group 671 shown in FIG. 130 (1) indicates that the three-digit symbols of the left symbol, the middle symbol, and the right symbol fluctuate uniformly, and the special symbol variation display game is in a variation display state. The small symbol group 672 shown in FIG. 130 (2) indicates that the left symbol is stopped, the two-digit symbols of the middle symbol and the right symbol are uniformly fluctuated, and the special symbol variation display game is in a variation display state. . A small symbol group 673 shown in FIG. 130 (3) indicates that the two symbols of the left symbol and the middle symbol are stopped, the right symbol is uniformly varied, and the special symbol variation display game is in a variation display state. A small symbol group 674 shown in FIG. 130 (4) indicates that the two symbols of the left symbol and the right symbol are stopped, the middle symbol is uniformly changed, and the special symbol variation display game is in a variation display state.

  In this way, the gaming machine 10 can indicate that the special figure variation display game is in the variation display state without necessarily displaying all the symbols in a variation manner. At this time, the gaming machine 10 may perform a notice notification or a reliability notification by a stopped symbol.

  Next, as a modified example of the second embodiment, a gaming machine 10 that clearly shows a variable display state while changing the number of digits of symbols constituting a small symbol group will be described with reference to FIG. 131. FIG. 131 is a diagram illustrating an example (part 5) of a variation display mode of a small symbol group according to a modification of the second embodiment.

  A small symbol group 675 shown in FIG. 131 (1) indicates that the three-digit symbols of the left symbol, the middle symbol, and the right symbol are uniformly varied, and the special symbol variation display game is in the variation display state. A small symbol group 676 shown in FIG. 131 (2) indicates that the two-digit symbols of the left symbol and the right symbol are uniformly varied, and the special symbol variation display game is in a variation display state. A small symbol group 677 shown in FIG. 131 (3) indicates that one symbol is uniformly changed and the special symbol change display game is in a change display state. A small symbol group 678 shown in FIG. 131 (4) indicates that the four-digit symbol is uniformly changed and the special-figure change display game is in the change display state.

  In this way, the gaming machine 10 can indicate that the special figure variation display game is in the variation display state while changing the number of digits of the symbol without necessarily changing the number of digits of the symbol and displaying the variation. At this time, the gaming machine 10 may perform a notice notification or a reliability notification according to the number of digits of the displayed symbol.

  The small symbol group may include a dedicated symbol as in the large symbol group. For example, the small symbol group 677 displays one symbol in a variable manner. At this time, since the visibility of each symbol is improved, the small symbol group 677 may perform a variable display including a special symbol. For example, the small symbol group 677 can include “7”, “Replay”, “this”, “heat”, etc. in the dedicated symbol when the standard symbol is one alphabet from “A” to “G”. . For example, “To” of the dedicated symbol “7” indicates a win, “Replay” of the dedicated symbol indicates a pseudo-ream, and “Heat” of the dedicated symbol indicates the degree of expectation. In addition, the small symbol group 677 may be provided with a symbol corresponding to each mode (for example, a tiger mode or the like indicating a latent probability change) or a failure. According to this, the gaming machine 10 can also show the notice notice and the reliability notice while showing that the special figure change display game is in the change display state by the small symbol group 677, and further improvement of interest is realized.

  Further, in the small symbol group, when the number of digits of the symbol is reduced, the symbol may be enlarged as compared with before the number of digits of the symbol is reduced. For example, one symbol is enlarged as compared with the small symbol group 675,676,678. In addition, the small symbol group 677 displays one symbol in a variable manner, and at this time, the visibility of each symbol is improved, so that temporary stop display may be performed.

  Although the large symbol group and the small symbol group are displayed on the display device 41 in the second embodiment, they may be displayed on different display devices. For example, when the gaming machine 10 includes the second display device, the large symbol group displays the large symbol group on the display device 41 (first display device) and displays the small symbol group on the second display device. be able to. For example, when the gaming machine 10 guides the player to operate the push button 25 and the player's line of sight moves to the push button 25, the second display device is disposed in the vicinity of the push button 25. Thereby, the gaming machine 10 can indicate that the special figure variation display game is in the variation display state even when the player moves his / her line of sight to the push button 25. Note that the gaming machine 10 may include an operation unit such as the push button 25 and the second display device in an integrated manner, such as a touch panel.

  In addition, the gaming machine 10 may be provided with the second display device on the game board 30 or may be provided with the second display device on the front frame 12. The second display device may be a display device smaller than the display device 41 (for example, a sub liquid crystal display device, a 7 segment display device, a dot matrix display device, or the like). Further, the gaming machine 10 may move and display a small symbol group between the first display device and the second display device, or between the first display device and the second display device. The symbol group may be moved and displayed. For example, when the gaming machine 10 performs the battle effect shown on the screen 616 on the first display device, both the large symbol group and the small symbol group, or one of them can be moved and displayed on the second display device. it can. Thereby, the gaming machine 10 can enlarge the display area used for the display effect (for example, battle effect) in the first display device, or can immerse the player in the display effect.

  In addition, the gaming machine 10 may clearly distinguish an effect display area for effect display and a small symbol group display area for displaying a small symbol group by background display, partition display, isolation, or the like. Thereby, the gaming machine 10 can suppress that the effect display effect interferes with the small symbol group and the visibility of the small symbol group decreases.

  In addition, when the gaming machine 10 displays the fourth symbol separately from the decorative symbols (large symbol group and small symbol group), the gaming machine 10 may display the fourth symbol in the vicinity of the small symbol group. Note that the fourth symbol is a symbol showing the variable display state of the special symbol 1 or the special symbol 2 in synchronization with the special symbol 1 symbol display unit 53 or the special symbol 2 symbol display unit 54 in the collective display device 50. According to this, the gaming machine 10 can indicate that the special figure variation display game is in the variation display state in cooperation with the small symbol group and the fourth symbol. Note that the fourth symbol is not necessarily displayed on the display device 41 as long as it is visible from the front of the game board 30. For example, the fourth symbol is displayed by a display device such as an LED (or a display device such as an LCD) provided on a constituent member of the game board 30 such as the center case 40, the flow path forming member 42, and the board effect device 44. It may be.

  Further, the gaming machine 10 may arrange the small symbol group and the fourth symbol so as to sandwich the large symbol group. According to this, even if the player's line of sight concentrates on the large symbol group or there is an effect that the visibility of either the small symbol group or the fourth symbol is impaired, the gaming machine 10 It is possible to indicate that the special figure variation display game is in the variation display state by either of the symbols and the fourth symbol.

The gaming machine 10 of the second embodiment (including the modification) described above has the following characteristics in one aspect.
(1) The gaming machine 10 includes a first display device (collective display device 50), a second display device (display device 41), a main control unit (game control device 100), and a sub control unit (effect control device 300). ) And. The main control unit performs variable display control of the first identification information (this special figure: special figure 1, special figure 2) in the first display device. The sub control unit performs variable display control of the second identification information (large symbol group 601) and the third identification information (small symbol group 602) in the second display device based on a command received from the main control unit. The slave control unit performs variable display control of the second identification information and the third identification information in synchronization with the variable display control of the first identification information. When the sub-control unit switches the second identification information from the first variation display mode (explicit state: for example, screen 614) to the second variation display mode (unspecified state: for example, screen 616) and displays it on the second display device, The variation display mode of the third identification information is made uniform and displayed on the second display device.

(2) The first variation display mode in (1) is a display mode in which the second identification information is clearly shown, and the second variation display mode is a display mode in which the second identification information is not clearly shown.
(3) The first variation display mode of (1) is a display mode in which the second identification information is variably displayed at a predetermined speed, and the second variation display mode is a temporary stop display mode (for example, shaking) of the second identification information. Dynamic motion, etc.).

(4) The second identification information in (1) is identification information that occupies a larger display area than the third identification information.
(5) The third identification information in (1) is identification information located in the peripheral portion of the display area as compared with the second identification information.

(6) The second identification information and the third identification information in (1) are each a symbol group composed of one or more symbols.
(7) The symbols constituting the second identification information of (6) are displayed larger than the symbols constituting the third identification information.

(8) The symbols constituting the third identification information of (6) are displayed with a fixed size.
(9) The symbols constituting the third identification information of (6) are the second timing at which the first symbol replacement is performed at the first timing after the lapse of the predetermined time after the start of the variable display and the variable display is stopped. Perform the second symbol replacement.

In addition, the gaming machine 10 of the above-described second embodiment (including the modified example) has the following characteristics in one aspect.
(1) The gaming machine 10 includes a first display device (collective display device 50), a second display device (display device 41), a main control unit (game control device 100), and a sub control unit (effect control device 300). ) And. The main control unit performs variable display control of the first identification information (this special figure: special figure 1, special figure 2) in the first display device. The sub control unit performs variable display control of the second identification information (large symbol group 601) and the third identification information (small symbol group 602) in the second display device based on a command received from the main control unit. The slave control unit performs variable display control of the second identification information and the third identification information in synchronization with the variable display control of the first identification information. The slave control unit starts to display the second identification information and the third identification information in synchronization with the first identification information variation display control, and displays the third identification information while hiding the second identification information. Then, the variable display of the second identification information and the third identification information is ended (for example, screens 631, 639).

(2) The second identification information and the third identification information in (1) are each a symbol group composed of one or more symbols.
(3) The sub-control unit of (1) displays a specific symbol (dedicated symbol) that is displayed only at a specific time before the second identification information is not displayed and the variable display is terminated.

(4) The slave control unit of (3) displays the specific symbol in a temporary stop display mode (for example, a swinging operation or the like).
(5) The specific symbol of (3) is displayed when the first identification information derives a predetermined result mode.

In addition, the gaming machine 10 of the above-described second embodiment (including the modified example) has the following characteristics in one aspect.
(1) The gaming machine 10 includes a first display device (collective display device 50), a second display device (display device 41), a main control unit (game control device 100), and a sub control unit (effect control device 300). ) And. The main control unit performs variable display control of the first identification information (this special figure: special figure 1, special figure 2) in the first display device. The sub control unit performs variable display control of the second identification information (large symbol group 601) and the third identification information (small symbol group 602) in the second display device based on a command received from the main control unit. The slave control unit performs variable display control of the second identification information and the third identification information in synchronization with the variable display control of the first identification information. The slave control unit displays the second identification information and the third identification in a synchronous variation display mode (for example, synchronous variation display at time T2 from timing t11 to timing t12) in which the second identification information and the third identification information are displayed in a synchronized manner. In an asynchronous variation display mode (for example, asynchronous variation display at time T3 from timing t12 to timing t16) in which information is displayed on the second display device and then the second identification information and the third identification information are variably displayed without synchronization. When displaying the second identification information and the third identification information on the second display device, the variation display mode of the second identification information is made non-uniform (for example, varies at an indefinite speed), and the variation display mode of the third identification information is changed. Display uniformly (for example, at a constant speed).

(2) In the synchronous variation display mode of (1), the display mode of the second identification information has a correspondence relationship with the display mode of the third identification information.
(3) In the asynchronous variation display mode of (1), the display mode of the second identification information has no correspondence with the display mode of the third identification information.

(4) When the third identification information of (1) displays a combination of two or more symbols (for example, the left symbol, the right symbol, and the middle symbol), the arrangement of one symbol is different from the arrangement of other symbols.
(5) When the secondary control unit of (1) changes the offset of the second identification information (change less than one symbol), the change amount of the third identification information is rounded up to one symbol and changes.

[Third Embodiment]
Next, the gaming machine 10 of the third embodiment (including the modification) will be described with reference to FIGS. 132 to 143. The gaming machine 10 shown in the third embodiment has a large symbol group and a small symbol group as two sets of decorative symbols, and for the large symbol group, a variable display control by a movie symbol and a variable display control by a non-movie symbol. Can be done. First, a movie symbol and a non-movie symbol in the large symbol group will be described with reference to FIG. FIG. 132 is a diagram illustrating an example of a symbol arrangement of a large symbol group according to the third embodiment.

  The movie symbol is a symbol displayed by a moving image reproduced by the effect control device 300. The effect control device 300 can store a moving image as a reproduction content in a memory (for example, the image ROM 325) in advance, read out the moving image from the memory (expand it if necessary), and reproduce the display of the movie symbol. . Therefore, the movie symbol is a symbol displayed by reproducing a moving image stored in advance in the memory.

  The non-movie symbol is a symbol displayed by a moving image generated by the effect control device 300. The effect control device 300 can store image information in a memory (for example, the image ROM 325) in advance, read the image information from the memory (expand as necessary), and generate a moving image that displays non-movie symbols. . Therefore, the non-movie symbol is a symbol displayed by a moving image generated from image information stored in advance in the memory.

  The non-movie symbols include symbols 700, 702, 704, 706, and 708, which can be symbols constituting a jackpot, and symbols 701, 703, 705, 707, and 709, which cannot be symbols that constitute a jackpot, in the symbol array.

  The symbols 700, 702, 704, 706, and 708 can be distinguished from other symbols by different display modes. The symbols 700, 702, 704, 706, and 708 are discriminated by a graphic element 711 having a distinctiveness as a symbol and a character (for example, a number) on a disk-like base 700 that is an outer shape of the symbol. Is attached to the character element 712.

  Symbols 701, 703, 705, 707, and 709 are blank symbols, and cannot be distinguished from other blank symbols by the same display mode. Each of the symbols 701, 703, 705, 707, and 709 is provided with a graphic element 714 having discriminability as a blank symbol by a graphic (for example, a musical note) on a disk-shaped base 713 having an external shape of the symbol.

  The movie symbol includes symbols 715, 716, 717, 718, and 719, which can be symbols constituting a big hit, in the symbol array. The symbols 715, 716, 717, 718, and 719 can be distinguished from other symbols by different display modes. Each of the symbols 715, 716, 717, 718, and 719 has a graphic element 721 having a distinctiveness as a symbol by a graphic (for example, a character) on a rectangular base 720 to which an S-shaped design that is the outer shape of the symbol is applied. Is attached. In addition, the symbols 715, 716, 717, 718, and 719 have distinctiveness as symbols depending on the colors attached to the base 720.

  Next, display effects of the gaming machine 10 according to the third embodiment will be described with reference to FIGS. 133 to 138. FIG. 133 is a diagram illustrating an example of an effect flow according to the third embodiment. FIG. 134 is a diagram illustrating an example (part 1) of a screen displayed by the display device according to the third embodiment. FIG. 135 is a diagram illustrating an example (part 2) of a screen displayed by the display device according to the third embodiment. FIG. 136 is a diagram illustrating an example (part 3) of a screen displayed by the display device of the third embodiment. FIG. 137 is a diagram illustrating an example (No. 4) of a screen displayed by the display device of the third embodiment. FIG. 138 is a diagram illustrating an example (No. 5) of a screen displayed by the display device of the third embodiment.

  [Production Flow F110] The gaming machine 10 stops and displays the symbols before the start of the change in the change display game. A screen 730 shown in FIG. 134 (F110) includes a large symbol group 731, a small symbol group 732, a special figure 1 hold number display 733, a special figure 2 hold number display 734, a hold display 735, and a hold digest display 736. Is included in the display content.

  Screen 730 shows a state where large symbol group 731 and small symbol group 732 are stopped. The large symbol group 731 includes an upper right symbol 731a, a lower left symbol 731b, an upper left symbol 731c, a lower right symbol 731d, and a central symbol 731e. The gaming machine 10 displays the large symbol group 731 during the stop display with the non-movie symbols.

  The large symbol group 731 is a first effective line that forms a symbol combination that hits a left-downward diagonal line formed by the upper right symbol 731a, the lower left symbol 731b, and the central symbol 731e. In addition, the large symbol group 731 is a second effective line that forms a symbol combination that hits a diagonally left upward line formed by the upper left symbol 731c, the lower right symbol 731d, and the central symbol 731e.

  At this time, the hold-up display 736 indicates that the special figure fluctuation display game is not in the fluctuation display state by a blank display, and the hold display 735 indicates that the total hold memory number of the special figure 1 game and the special figure 2 game is “8”. It shows that there is. The total holding memory number “8” indicated by the holding display 735 is the holding number “4” of the special figure 1 game indicated by the special figure 1 holding number display 733 and the holding of the special figure 2 game indicated by the special figure 2 holding number display 734. This is the total number with the storage number “4”. When the gaming machine 10 starts the symbol variation, the game machine 10 proceeds to the effect flow F111.

  [Production flow F111] The gaming machine 10 starts variable display. The gaming machine 10 displays the large symbol group 731 with the non-movie symbols after starting the variable display. A screen 738 shown in FIG. 134 (F111) indicates that the large symbol group 731 and the small symbol group 732 have started the variable display. For example, the large symbol group 731 performs a variable display by rotating the vertical axis in the counterclockwise direction, and the small symbol group 732 performs a variable display by vertically scrolling each symbol from the upward direction to the downward direction. At this time, the gaming machine 10 sets the large symbol group 731 in a semi-transparent state, thereby improving the visibility of the background display over the visibility of the large symbol group 731. On the other hand, the gaming machine 10 ensures the visibility prioritizing the background display without making the small symbol group 732 translucent.

  In addition, the special figure 2 hold number display 734 displays the special figure 2 game with the stored memory number reduced by one, and the hold display 735 displays the special figure variable display game with the reserved memory number reduced by one. . The reserved digest display 736 indicates that the special figure variation display game is in the variation display state. The gaming machine 10 proceeds to the production flow F112 when it is “out of” without performing the movie production, proceeds to the production flow F113 when it is “winning” without performing the movie production, and produces when the movie production is performed. Proceed to flow F114.

  [Production Flow F112] The gaming machine 10 stops and displays the symbol. The gaming machine 10 displays a large symbol group 731 when a symbol is stopped and displayed, using a non-movie symbol. A screen 740 shown in FIG. 134 (F112) shows a state in which the large symbol group 731 and the small symbol group 732 stop changing display, and the large symbol group 731 and the small symbol group 732 are stopped and displayed in a dislocation manner. . At this time, the reserved digest display 736 indicates that the special figure variation display game is not in the variation display state by a blank display.

  [Production flow F113] The gaming machine 10 stops and displays the symbols. The gaming machine 10 displays a large symbol group 731 when a symbol is stopped and displayed, using a non-movie symbol. A screen 742 shown in FIG. 134 (F113) shows a state in which the large symbol group 731 and the small symbol group 732 stop changing display, and the large symbol group 731 and the small symbol group 732 stop and display in a hit state. . At this time, the reserved digest display 736 indicates that the special figure variation display game is not in the variation display state by a blank display.

  [Production Flow F114] The gaming machine 10 displays all blanks on the large symbol group 731. The gaming machine 10 displays the large symbol group 731 when displaying all blanks as a non-movie symbol. A screen 744 shown in FIG. 135 (F114) shows a state in which the large symbol group 731 is stopped and displayed in all blanks. The all blank is a display mode in which all of the upper right symbol 731a, the lower left symbol 731b, the upper left symbol 731c, the lower right symbol 731d, and the central symbol 731e constituting the large symbol group 731 are blank symbols. All-blank is an example of a display mode for guiding the player to enter the movie effect, and other symbol combinations in the large symbol group 731 may be used as the entry event for the movie effect. In addition, since the gaming machine 10 clearly indicates that the small symbol group 732 is being variably displayed, the large symbol group 731 when displaying all blanks may be used as the temporary stop display mode or the stop display mode. . The gaming machine 10 displays all blanks on the large symbol group 731 and then proceeds to the effect flow F115.

  [Production Flow F115] The gaming machine 10 starts a movie production (movie 1). The gaming machine 10 displays the large symbol group 731 by switching to the movie symbol in the movie effect. A screen 746 shown in FIG. 135 (F115) superimposes a small symbol group 732, a special figure 1 reservation number display 733, and a special figure 2 reservation number display 734 on the movie screen 747. Therefore, the gaming machine 10 can clearly indicate the variable display state of the special figure variable display game, the reserved memory number of the special figure 1 game, and the reserved memory number of the special figure 2 game even during the movie production.

  The movie screen 747 is a playback image of a movie (moving image) prepared in advance. The movie screen 747 in the screen 746 includes reach configuration symbols 748 and 749 and a symbol list display 750 in the display content. The reach composition symbol 748 is displayed at the upper left of the movie screen 747, and the reach composition symbol 749 is displayed at the upper right of the movie screen 747. The symbol list display 750 displays a list of movie symbols 750a, 750b, 750c, 750d, and 750e. For example, the symbol list display 750 displays a list of movie symbols 750a, 750b, 750c, 750d, and 750e that are moved and displayed in an arc. After displaying the movie 1, the gaming machine 10 proceeds to the effect flow F116.

  [Production flow F116] The gaming machine 10 continues the movie production (movie 2). A screen 752 shown in FIG. 135 (F116) superimposes and displays a small symbol group 732, a special figure 1 hold number display 733, and a special figure 2 hold number display 734 on the movie screen 747. The movie screen 747 in the screen 752 includes reach composition symbols 748 and 749 and a character 753 in the display content. Thereby, the gaming machine 10 can display the character 753 only by playing a movie prepared in advance without performing the image generation processing for the character 753, and the processing load on the effect control device 300 can be reduced. . After displaying the movie 2, the gaming machine 10 proceeds to the effect flow F117.

  [Production flow F117] The gaming machine 10 continues the movie production (movie 3). A screen 756 shown in FIG. 135 (F117) superimposes and displays a small symbol group 732, a special figure 1 hold number display 733, and a special figure 2 hold number display 734 on the movie screen 747. The movie screen 747 in the screen 756 includes reach configuration symbols 748 and 749, a character 753, and a symbol list display 757 as display contents. For example, the symbol list display 757 displays a list of five types of movie symbols. The gaming machine 10 can freely change the display mode such as the position, size, and inclination of the movie symbol on the movie screen 747 by simply playing a prepared movie without overloading the processing load on the effect control device 300. Can be done. After displaying the movie 3, the gaming machine 10 proceeds to the production flow F118.

  [Production flow F118] The gaming machine 10 continues the movie production (movie 4). A screen 758 shown in FIG. 136 (F118) displays a small symbol group 732, a special figure 1 hold number display 733, and a special figure 2 hold number display 734 superimposed on the movie screen 747. The movie screen 747 in the screen 758 includes reach configuration symbols 748 and 749, a character 753, and symbol group displays 759 and 760 in the display content. For example, the symbol group displays 759 and 760 display one type of movie symbol nine by nine. The symbol group displays 759 and 760 each display the character “?” By a group of movie symbols. The symbol group display 759 displays the normal character “?”, And the symbol group display 760 displays the inverted character “?”. The character “?” Indicated by the symbol group displays 759 and 760 corresponds to the display mode (for example, facial expression, attitude, gesture, etc.) of the character 753, and explains how the character 753 is thinking. In other words, the gaming machine 10 realizes an effect explanation function in a movie effect by a display form formed by a group of movie symbols. After displaying the movie 4, the gaming machine 10 proceeds to the effect flow F119.

  [Production flow F119] The gaming machine 10 continues the movie production (movie 5). A screen 762 shown in FIG. 136 (F119) superimposes and displays a small symbol group 732, a special figure 1 hold number display 733, and a special figure 2 hold number display 734 on the movie screen 747. The movie screen 747 in the screen 762 includes reach configuration symbols 748 and 749, a character 753, and a movie symbol 763 in the display content. The movie symbol 763 is displayed at a position corresponding to the mouth of the character 753 such as a pig. After displaying the movie 5, the gaming machine 10 proceeds to the effect flow F120.

  [Production Flow F120] The gaming machine 10 continues the movie production (movie 6). A screen 764 shown in FIG. 136 (F120) superimposes a small symbol group 732, a special figure 1 hold number display 733, and a special figure 2 hold number display 734 on the movie screen 747. The movie screen 747 in the screen 764 includes reach composition symbols 748 and 749, characters 753, 765 and 766, movie symbols 763, and lines 767. The characters 765 and 766 function as liveliness in the movie effect, and the dialogue 767 displays the dialogue “OK” that the character 753 emits. After displaying the movie 6, the gaming machine 10 proceeds to the effect flow F121.

  [Production Flow F121] The gaming machine 10 continues the movie production (movie 7). A screen 768 shown in FIG. 136 (F121) superimposes a small symbol group 732, a special figure 1 hold number display 733, and a special figure 2 hold number display 734 on the movie screen 747. The movie screen 747 in the screen 768 includes reach composition symbols 748 and 749, characters 753, 765 and 766, a symbol group display 769 and a dialogue 767. In addition, the gaming machine 10 outputs a sound 770 corresponding to “O (O)” among the lines 767 from the speakers 19 a and 19 b. The symbol group display 769 displays the letter “O” using nine types of movie symbols. At this time, the symbol group display 769 is superimposed on the character 753 to clearly indicate that the speaker of the voice 770 is the character 753. Thereby, the gaming machine 10 can enhance the effect by synchronizing the symbol group display 769 displayed on the display device 41 and the sound output from the speakers 19a and 19b (sound output device). Further, the gaming machine 10 can assist the understanding of the contents by the symbol group display 769 even when the sound 770 output from the speakers 19a and 19b may be difficult for the player to hear because the volume is low. Therefore, the gaming machine 10 can exert a game effect even if a large volume is not set. After displaying the movie 7, the gaming machine 10 proceeds to the effect flow F122.

  [Production Flow F122] The gaming machine 10 continues the movie production (movie 8). A screen 772 shown in FIG. 137 (F122) superimposes and displays a small symbol group 732, a special figure 1 hold number display 733, and a special figure 2 hold number display 734 on the movie screen 747. The movie screen 747 in the screen 772 includes reach composition symbols 748 and 749, characters 753, 765 and 766, a symbol group display 773 and a dialogue 767. Further, the gaming machine 10 outputs a sound 774 corresponding to “K (K)” out of the lines 767 from the speakers 19 a and 19 b. The symbol group display 773 displays the character “K” using nine types of movie symbols. At this time, the symbol group display 773 indicates that the speaker of the voice 774 is the character 753 by being superimposed on the character 753. After displaying the movie 8, the gaming machine 10 proceeds to the effect flow F123.

  Note that the gaming machine 10 performs the symbol group display in syllable units in the sound output from the speakers 19a and 19b, but may perform the symbol group display in semantic units. Moreover, although the game machine 10 guided the sound output from the speakers 19a and 19b with alphabets, it may be numbers, hiragana, katakana, kanji, symbols, or pictograms. For example, the gaming machine 10 can display “NA” and “NA” by two symbol group displays when the speakers 19a and 19b output the voice “NANA”, and “7” or “NA” by one symbol group display. “Seven” can be displayed. In addition, the gaming machine 10 can display “MA” and “RU” by two symbol group displays when the speakers 19a and 19b output the voice “maru”, and “circle” and “R” by one symbol group display. ○ ”can be displayed. In addition, when the gaming machine 10 displays two or more symbol groups, it may be displayed simultaneously on one screen, or may be displayed with a time difference by switching or scrolling.

  [Production Flow F123] The gaming machine 10 continues the movie production (movie 9). A screen 776 shown in FIG. 137 (F123) superimposes and displays a small symbol group 732, a special figure 1 hold number display 733, and a special figure 2 hold number display 734 on the movie screen 747. The movie screen 747 in the screen 776 includes reach composition symbols 748 and 749, a character 753, and a symbol list display 777. After displaying the movie 9, the gaming machine 10 proceeds to the production flow F124.

  [Production Flow F124] The gaming machine 10 continues the movie production (movie 10). A screen 778 shown in FIG. 137 (F124) superimposes a small symbol group 732, a special figure 1 reservation number display 733, and a special figure 2 reservation number display 734 on the movie screen 747. The movie screen 747 in the screen 778 includes reach configuration symbols 748 and 749 and a movie symbol 779 in the display content. The gaming machine 10 displays the fluctuation state of the movie symbol 779 (for example, whether or not the movie symbol 779 stops) by the movie effect. After displaying the movie 10, the gaming machine 10 proceeds to the effect flow F125.

  [Production Flow F125] The gaming machine 10 continues the movie production (movie 11). A screen 780 shown in FIG. 137 (F125) displays a small symbol group 732, a special figure 1 hold number display 733, and a special figure 2 hold number display 734 superimposed on the movie screen 747. The movie screen 747 in the screen 780 includes reach configuration symbols 748 and 749 and a movie symbol 781 as display contents. The gaming machine 10 displays the stop state of the movie symbol 781 by the movie effect. That is, the movie screen 747 displays a stop mode (for example, a big hit mode) in which the reach configuration symbols 748 and 749 and the movie symbol 781 are aligned. Note that the gaming machine 10 clearly indicates that the special figure game is still in the variable display state by the small symbol group 732. Further, although the movie screen 747 is a movie screen for deriving a hit, the gaming machine 10 can separately prepare a movie screen that does not derive a hit, that is, a movie screen that is “out of”. When deriving the deviation, the gaming machine 10 moves to the effect flow F112 without shifting to the effect flow F125 after the effect flow F124. When the winning is derived, the gaming machine 10 proceeds to the effect flow F126, the effect flow F127, or the effect flow F128.

  [Production flow F126] The gaming machine 10 displays the variable display result after the movie production is completed. The screen 782 shown in FIG. 138 (F126) displays the large symbol group 731 in a non-movie symbol in a symbol combination manner corresponding to the winning combination and stops displaying the small symbol group 732 in a symbol combination manner corresponding to the winning symbol. Indicates the state. At this time, the reserved digest display 736 indicates that the special figure variation display game is not in the variation display state by blank display. In this way, the gaming machine 10 can switch from the result display of the special figure variation display game by the movie symbol to the result display of the special figure variation display game by the non-movie symbol by the end of the movie effect. Thereby, the gaming machine 10 can clearly show the details of the result mode by displaying the result by the non-movie symbol while exhibiting the effect of the movie display.

  [Production Flow F127] The gaming machine 10 continues the movie effect and displays the variable display result. A screen 784 shown in FIG. 138 (F127) shows a state in which the large symbol group 731 is hidden and the small symbol group 732 is stopped and displayed in a symbol combination manner corresponding to the winning combination. The screen 784 displays a variable display result guidance display 785 and a character 786. The fluctuation display result guidance display 785 and the character 786 guide that a win (for example, a big hit) has been derived as a result of the special figure fluctuation display game. Note that the screen 784 may be included in the movie effect, or may not be included in the movie effect.

  [Production Flow F128] The gaming machine 10 performs re-variable display after the end of the movie production. A screen 788 shown in FIG. 138 (F128) re-variably displays the large symbol group 731 in a symbol combination manner corresponding to the hit by the non-movie symbol, and clearly indicates that the small symbol group 732 is being variably displayed.

  [Production Flow F129] The gaming machine 10 displays the variation display result after the end of the variation display. The screen 790 shown in FIG. 138 (F129) displays the large symbol group 731 in a non-movie symbol in a symbol combination manner corresponding to the win and stops displaying the small symbol group 732 in a symbol combination manner corresponding to the hit. Indicates the state. As described above, the gaming machine 10 can switch from the result display of the special figure variation display game by the movie symbol to the result display of the special figure variation display game through the re-variation display by the non-movie symbol by the end of the movie effect. Thereby, the gaming machine 10 can clearly show the details of the result mode by displaying the result by the non-movie symbol while exhibiting the effect of the movie display.

  Note that the gaming machine 10 has been described by dividing the movie display from the movie 1 to the movie 11 for the sake of convenience, but a movie effect may be performed by one playback moving image, or a plurality of playback moving images that are sequentially played back. A movie presentation may be performed.

  In this way, the gaming machine 10 can separate each development process by making the symbol (movie symbol) in the movie effect different from the symbol (non-movie symbol) in the non-movie effect. For example, the gaming machine 10 does not affect the moving image used in the movie effect even if the display mode or number of symbols used in the non-movie effect is changed. Further, the gaming machine 10 can share the moving image used for the movie effect even if the display mode and the number of the symbols used for the non-movie effect are different among the series machines. Therefore, the gaming machine 10 can be a gaming machine that can be supplied to the market at a low cost by reducing the development man-hours.

  Here, a modified example of the symbol group displays 769 and 773 will be described with reference to FIGS. 139 and 140. FIG. 139 is a diagram illustrating a modification (No. 1) of the symbol group display according to the third embodiment. FIG. 140 is a diagram illustrating a modification (No. 2) of the symbol group display according to the third embodiment.

  In the symbol group display 791 shown in FIG. 139 (1), the character “O” is formed by 18 symbols 719 (see FIG. 132). In this way, the gaming machine 10 can arbitrarily change the number of symbols forming the character. Further, the gaming machine 10 may change the number of symbols forming the characters in accordance with the progress of the variable display game and the result derived from the variable display game. For example, when the gaming machine 10 displays the symbol group corresponding to the letter “O”, the symbol group display 769 (see FIG. 136) is displayed when the jackpot reliability is 10%, and the jackpot reliability is 50. When it is%, the symbol group display 791 can be displayed.

  In the symbol group display 792 shown in FIG. 139 (2), the character “O” is formed by nine symbols 715 (see FIG. 132). Thus, the gaming machine 10 can arbitrarily change the type of symbols forming the characters. In addition, the gaming machine 10 may change the type of symbol forming the character in accordance with the progress of the variable display game or the result derived from the variable display game. For example, when the gaming machine 10 displays the symbol group corresponding to the letter “O”, the symbol group display 769 is displayed when the jackpot reliability is 10%, and the symbol group display is displayed when the jackpot reliability is 50%. A group display 792 can be displayed.

  The symbol group display 793 shown in FIG. 139 (3) forms the character “O” with nine symbols 719 (see FIG. 132) and performs symbol arrangement different from the symbol group display 769. In the symbol group display 793, the symbol arrangement is shifted by a half of the symbol compared to the symbol group display 769. Thus, the gaming machine 10 can arbitrarily change the arrangement (mode) of the symbols forming the characters. Further, the gaming machine 10 may change the arrangement of the symbols forming the characters in accordance with the progress of the variable display game and the result derived from the variable display game. For example, when the gaming machine 10 displays the symbol group corresponding to the letter “O”, the symbol group display 769 is displayed when the jackpot reliability is 10%, and the symbol group display is displayed when the jackpot reliability is 50%. A group display 793 can be displayed.

  Further, the gaming machine 10 can display characters by a trajectory in which one or more symbols move instead of displaying characters by a group of symbols such as symbol group displays 769 and 773.

  In the symbol locus display 794 shown in FIG. 140 (1), the character “O” is formed by a locus on which one moving display symbol 794a including the symbol 719 moves and displays. Also, the symbol trajectory display 795 shown in FIG. 140 (2) forms the letter “O” with the trajectory that the two moving display symbols 795a and 795b composed of the symbol 719 move and display. Note that the gaming machine 10 may display the afterimages by the movement display of the movement display symbols 794a, 795a, and 795b to clearly indicate the trajectory. In addition, the gaming machine 10 may change the number and type of symbols that form characters based on the trajectory in accordance with the progress of the variable display game and the result derived by the variable display game. For example, when the gaming machine 10 displays the symbol trajectory corresponding to the character “O”, the symbol trajectory display 794 is displayed when the jackpot reliability is 10%, and the symbol trajectory when the jackpot reliability is 50%. A trajectory display 795 can be displayed.

  In the symbol locus display 796 shown in FIG. 140 (3), the character “K” is formed by a locus on which one moving display symbol 796a including the symbol 719 moves and displays. For example, the movement display symbol 796a displays the locus by moving from the start point 797a to the intermediate end point 797b to display the locus, and then moves and displays from the intermediate end point 797c to the end point 797d. Also, the symbol trajectory display 798 shown in FIG. 140 (4) forms the character “K” with the trajectory that the two moving display symbols 798a and 798b composed of the symbol 719 move and display. For example, the movement display symbol 798a displays a locus by moving from the start point 799a to the end point 799b, and the movement display symbol 798b displays a locus by moving from the start point 799c to the end point 799d. In addition, the gaming machine 10 may change the number and type of symbols that form characters based on the trajectory in accordance with the progress of the variable display game and the result derived by the variable display game. For example, when the gaming machine 10 displays the symbol trajectory corresponding to the letter “K”, it displays the symbol trajectory display 796 when the jackpot reliability is 10%, and the symbol trajectory when the jackpot reliability is 50%. A trajectory display 798 can be displayed.

  The gaming machine 10 tried to display characters corresponding to the sound output from the sound output device in relation to the game effect in the variable display game, but corresponds to the sound output related to the notification of an error or the like. It is also possible to display characters to be displayed. Moreover, the characters to be displayed by the symbol group display or the symbol trajectory display are not limited to characters in a narrow sense, and may include numbers and pictograms.

  Next, switching timing between the movie symbol and the non-movie symbol will be described with reference to FIG. FIG. 141 is a timing chart showing an example of switching timing between the movie symbol and the non-movie symbol according to the third embodiment.

  The game control device 100 transmits a command (for example, a stop symbol command, a variation pattern command, a hold command, a stop command, etc.) related to the variable display to the effect control device 300. The effect control device 300 receives a command (for example, a stop symbol command, a variation pattern command, a hold command, etc.) regarding the variable display start from the game control device 100 and starts variable display of the large symbol group 731 and the small symbol group 732. . Further, the production control device 300 ends the variable display of the large symbol group 731 and the small symbol group 732 according to a time management based on a command related to the variable display start or a command related to the variable display end (for example, a stop command).

  The timing chart TC11 shows a state in which the effect control device 300 performs the variable display from the timing t11 to the timing t13 with respect to the special figure 1 or the special figure 2, and performs the stop display after the timing t13. The effect control device 300 performs the fluctuation display (movie fluctuation) on the movie screen from the timing t12 to the timing t13 after performing the fluctuation display (non-movie fluctuation) that does not depend on the movie screen from the timing t11 to the timing t12, and after the timing t13. The stop display is not performed regardless of the movie screen.

  The timing chart TC12 shows the switching timing between the movie symbol and the non-movie symbol in the variable display. The production control device 300 displays the non-movie symbol in the non-movie variation from timing t11 to timing t12, displays the movie symbol in the movie variation from timing t12 to timing t13, and displays the non-movie symbol in the stop display after timing t13. Is displayed.

  For example, the effect control device 300 can set the first half of the variable display as non-movie fluctuation and the reach effect as the second half of the variable display as movie fluctuation. Thereby, the gaming machine 10 can separate the fluctuation accompanied by the reach production with a large development man-hour from the fluctuation caused by the non-movie symbol related to the performance determination of the gaming machine 10.

  Next, a modified example of the switching timing between the movie symbol and the non-movie symbol will be described with reference to FIG. FIG. 142 is a timing chart showing a modification example (part 1) of the switching timing between the movie symbol and the non-movie symbol according to the third embodiment.

  The timing chart TC21 shows a state in which the effect control device 300 performs the variable display from the timing t21 to the timing t24 for the special figure 1 or the special figure 2 and performs the stop display after the timing t24. The production control device 300 performs non-movie variation from timing t21 to timing t22, then performs movie variation from timing t22 to timing t23, performs non-movie variation again from timing t23 to timing t24, and movie screen after timing t24. A stop display that does not depend on is displayed.

  The timing chart TC22 shows the switching timing between the movie symbol and the non-movie symbol in the variable display. The production control device 300 displays a non-movie symbol in the non-movie variation from timing t21 to timing t22, displays a movie symbol in the movie variation from timing t22 to timing t23, and displays non-movie variation and stop after timing t23. In non-movie design. Thereby, the gaming machine 10 can ensure the re-variable display period T1 from t23 to timing t24. The gaming machine 10 can facilitate the matching between the movie change and the result display by securing the re-change display period T1, and further strengthens the separation between the change accompanied by the reach effect and the change caused by the non-movie symbol. be able to.

  In addition, as shown in the timing chart TC23, the effect control apparatus 300 may use a pseudo movie symbol in the re-variable display period T1. The pseudo movie symbol is equivalent to the movie symbol on the display, and is equivalent to the non-movie symbol on the control. That is, the production control device 300 does not display the pseudo movie symbol by playing the moving image, but displays the pseudo movie symbol by an image generated in the same manner as the non-movie symbol.

  Next, another example of the modification timing of switching between the movie symbol and the non-movie symbol will be described with reference to FIG. FIG. 143 is a timing chart illustrating a modification (No. 2) of the switching timing between the movie symbol and the non-movie symbol according to the third embodiment.

  The timing chart TC31 shows a state in which the effect control device 300 performs the variable display from the timing t31 to the timing t33 with respect to the special figure 1 or the special figure 2, and performs the stop display after the timing t33. The effect control device 300 performs non-movie variation from timing t31 to timing t32, then performs movie variation from timing t32 to timing t33, and performs stop display on the movie screen after timing t33.

  The timing chart TC32 shows the switching timing between the movie symbol and the non-movie symbol in the variable display. The effect control device 300 displays the non-movie symbol in the non-movie variation from timing t31 to timing t32, displays the movie symbol in the movie variation from timing t32 to timing t33, and displays the movie symbol and the symbol in the stop display after timing t33. Hide non-movie symbols.

  The timing chart TC33 shows the display timing of the small symbol group 732 in the variable display. The effect control device 300 displays the small symbol group 732 in the stop display period after the timing t33 in addition to the variable display period from the timing t31 to the timing t33. That is, the effect control device 300 displays the small symbol group 732 while not displaying the symbol corresponding to the large symbol group in the stop display after the timing t33. As a result, the gaming machine 10 does not have to display the result form of the symbol corresponding to the large symbol group, so that it is possible to easily match the movie variation and the result display, and to detect the variation with the reach effect. It is possible to further strengthen the separation from fluctuations due to movie designs.

  Note that the small symbol group 732 is not necessarily displayed in the variable display period from the timing t31 to the timing t33. For example, as shown in the timing chart TC34, the effect control apparatus 300 may hide the small symbol group 732 from timing t31 to timing t32 and display the small symbol group 732 after timing t32. As a result, the gaming machine 10 can clearly indicate the change display state during the movie change by the small symbol group 732, so that the degree of freedom of the effect display in the movie change can be improved and the entertainment can be further improved.

The gaming machine 10 of the above-described third embodiment (including the modified example) has the following characteristics in one aspect.
(1) The gaming machine 10 includes variable display control means (game control device 100, effect control device 300), voice control means (effect control device 300), and voice guidance display means (effect control device 300). The variable display control means performs variable display control of the identification information (large symbol group 601) in the display device (display device 41). The sound control means performs a game effect (game effect related to a variable display of identification information) by sound output from the sound output device (speakers 19a, 19b). The voice guidance display means displays the guidance corresponding to the voice output by the display mode of the identification information (design).

(2) The voice guidance display means of (1) performs guidance corresponding to voice output by means of characters including numbers, symbols, or pictograms.
(3) The voice guidance display means of (2) forms characters by a symbol group including two or more symbols.

(4) The voice guidance display means of (2) forms a character by a trajectory in which one or more symbols move.
(5) The voice guidance display means of (1) performs guidance corresponding to voice output in units of syllables.

(6) The voice guidance display means of (1) performs guidance corresponding to voice output in a semantic unit.
(7) The voice guidance display means of (1) displays two or more guidances simultaneously.
(8) The voice guidance display means of (1) displays two or more guidances with a time difference.

  (9) The voice guidance display means of (2) changes the display mode (type, size, number, arrangement, etc.) of the symbols that form characters corresponding to the progress of the variable display game and the results derived from the variable display game. change.

In addition, the gaming machine 10 of the above-described third embodiment (including the modification) has the following characteristics in one aspect.
(1) The gaming machine 10 includes a display device (display device 41) and a control unit (game control device 100, effect control device 300) that performs variable display control of identification information (symbols) in the display device. The control unit switches between a variable display reproduction control (movie fluctuation) for reproducing a moving image including a variation display of identification information and a variable display generation control (non-movie variation) for generating a moving image including a variation display of identification information. Is possible. The control unit displays the identification information in the first display mode (movie symbol) in the variable display reproduction control, and displays the identification information in the second display mode (non-movie symbol) in the variable display reproduction control.

(2) The control unit of (1) sets the first half of the variable display as the variable display generation control and the second half of the variable display as the variable display reproduction control.
(3) The control unit of (2) sets the identification information to be stopped and displayed after a predetermined variable display period as the second display mode.

  (4) The control unit of (2) displays the identification information to be stopped and displayed after the predetermined variable display period after switching from the variable display reproduction control to the variable display generation control before the predetermined variable display period elapses. To do.

[Fourth Embodiment]
Next, a gaming machine 10 according to a fourth embodiment (including modifications) will be described with reference to FIGS. 144 to 148. The gaming machine 10 shown in the fourth embodiment includes an accessory so as to hide a part of the display area of the display device 41, and performs a display effect in the display area hidden by the accessory. First, an overview of the display device 41 and the accessory at a normal viewpoint from the player will be described with reference to FIG. FIG. 144 is a diagram illustrating an example of an overview of the display device and the accessory according to the fourth embodiment.

  The display device 41 performs various displays regarding the variable display game in the display area 800. The display device 41 is attached to a recess provided in the center case 40 at a position deeper than the front surface of the center case 40, and the periphery of the display area is surrounded by the center case 40.

  The display area 800 includes a small symbol group 801, a special symbol hold number display 802, a large symbol group 803, and a hold display 813 in the display content. The small symbol group 801 is displayed at a position where it can be easily observed by the player, and clearly shows the variation display state of the special figure game. The special figure hold number display 802 is displayed at a position that can be easily observed by the player and clearly shows the number of special figure hold (starting memory number). The large symbol group 803 is in charge of the main display effect for the variable display of the special figure game. The hold display 813 corresponds to each hold of the special game.

  The center case 40 includes the roles 804 to 812 and the stage 814. The combinations 804 to 812 are arranged so as to overlap a part of the display area 800. Further, the objects 807 to 809 overlap the display area 800 via the stage 814. Note that a part or all of the actors 804 to 812 may be a movable body (for example, the board effect device 44) whose arrangement state is not fixed, or a fixed body whose arrangement state is fixed. Also good. Further, a part or all of the accessory 804 to the accessory 812 may be a decorative body (for example, a panel decoration device 46) that includes a light emitter such as an LED and decorates the game board 30.

  Next, the positional relationship between the display surface of the display device 40 and the accessory 809 will be described with reference to FIG. FIG. 145 is a diagram illustrating an example of the positional relationship between the display surface and the accessory of the display device according to the fourth embodiment.

  Since the stage 814 is positioned between the accessory 809 and the display surface 820 of the display device 40, the accessory 809 has a gap w1 between the display surface 820 and the accessory 809. The stage 814 may allow the game ball to roll on the stage while allowing the game ball to enter, or may not allow the game ball to enter. When allowing the game ball to roll on the stage, the stage 814 can clearly indicate the presence of the gap w1 between the accessory 809 and the display surface 820 by the game ball rolling on the stage. Note that the gaming machine 10 makes the accessory 809 through the operation of the movable accessory by making the accessory 809 a movable accessory or by making another accessory (for example, the accessory 808) a movable accessory. The presence of a gap w1 between the display surface 820 and the display surface 820 may be clearly indicated.

  Such a gaming machine 10 makes it possible for the normal observer v1 to observe the first observation region R1, and makes it difficult to observe the second observation region R2 where the accessory 809 interferes. However, the gaming machine 10 makes it possible to observe the second observation region R2 for the observer v2 who looks down on the lower direction of the display region 800. That is, the gaming machine 10 makes it possible to observe the second observation region R2 for the observer v2 who is interested in the second observation region R2.

  Next, the positional relationship between the display elements displayed in the display area 800 and the accessory 809 will be described with reference to FIGS. 146 and 147. FIG. 146 is a diagram (part 1) illustrating an example of the positional relationship between the effect display element and the accessory according to the fourth embodiment. FIG. 147 is a diagram (part 2) illustrating an example of the positional relationship between the effect display element and the accessory according to the fourth embodiment.

  FIG. 146 (1) shows a state in which the gaming machine 10 displays the effect display element 822 in the display area 800. The effect display element 822 is a display element in charge of an effect that makes the display content lively (for example, decorates with gorgeousness). The accessory 809 includes a semicircular main body portion and a plurality of substantially triangular decorative portions arranged along the periphery of the main body portion, and has a shape reminiscent of “sunflower”. The effect display element 822 has a function of being displayed so as to contact the outer edge of the accessory 809 and decorating the accessory 809. The effect display element 822 is displayed at a position (first observation region R1) that can be observed by a normal observer (observer v1).

  The effect display element 822 is a display element that gives an image of a leaf, decorates the accessory 809 by changing the display mode such as shaking, changing the color, changing the size, etc. The advance notice of the progress and result of the variable display game is made by the change. Therefore, the gaming machine 10 can urge the player to be interested in the effect display element 822.

  FIG. 146 (2) shows a state in which the gaming machine 10 displays the effect display element 823 in the display area 800. The effect display element 823 is one of the different display modes of the effect display element 822. The effect display element 823 is displayed at a position (second observation region R2) hidden by the accessory 809 when observed by a normal observer (observer v1). Therefore, a normal observer (observer v1) cannot observe the effect display element 823.

  However, the gaming machine 10 makes it possible to observe the effect display element 823 for an observer (observer v2) who looks down on the lower direction of the display area 800. In addition, the gaming machine 10 gives the player a motivation to observe the effect display element 823 because the advancement notification element 823 notifies the advance notice of the progress and result of the variable display game according to the display mode of the effect display element 823.

  Thereby, the gaming machine 10 can arouse the observer's inquiring mind to the observer (player) who is interested in the effect display element 823. In addition, the gaming machine 10 can give the player a sense of satisfaction for observing the effect display element 823, and thus a sense of satisfaction for the game, by causing the player to move the observation position. Such a gaming machine 10 can produce a new discovery by the player's active behavior and can entertain the player for a long period of time.

  Note that the gaming machine 10 does not necessarily have to display the effect display element 823 at a position hidden by the accessory 809 as long as it is a position that is not observed by a normal observer (observer v1). For example, the gaming machine 10 may display the effect display element 823a at a position hidden in the accessory 810 instead of the accessory 809. Further, the gaming machine 10 may display the effect display element 823a at a position hidden in the accessory 810 in addition to the accessory 809. Thereby, the gaming machine 10 can increase the difficulty of observing the effect display element 823a, and can give a high degree of satisfaction to a player who has a lot of gaming experience.

  Further, when displaying the effect display element 823, the gaming machine 10 may display a notification element 823b that notifies that the effect display element 823 is being displayed. Thereby, the gaming machine 10 can provide guidance to the beginner that the effect display element 823 is being displayed, and can provide an interest that is not constrained by a lot of gaming experience.

  FIG. 147 (1) shows a state in which the gaming machine 10 displays the effect display element 824 in the display area 800. The effect display element 824 is displayed at a position (first observation region R1) that can be observed by a normal observer (observer v1). The effect display element 824 is a display element that images a flower, and is displayed in one of the display modes changed from the effect display element 822.

  Thus, when changing the display mode of the effect display element 822, the gaming machine 10 does not necessarily need to be displayed at a position (second observation region R2) hidden behind the accessory 809 like the effect display element 823. . When changing the display mode of the effect display element 822, the gaming machine 10 may display the effect display element 824 at a position (first observation region R1) that can be observed by a normal observer (observer v1). . Thereby, the gaming machine 10 can widely inform the player of the change in the display mode of the effect display element 822.

  FIG. 147 (2) shows a state in which the gaming machine 10 displays the effect display element 825 in the display area 800. The effect display element 825 is one of the different display modes of the effect display element 822. The effect display element 825 is displayed at a position (second observation area R2) that is hidden by the accessory 809 when observed by a normal observer (observer v1), and is an observer who looks down on the downward direction of the display area 800 ( It is displayed so as to be observable by the observer v2).

  In this way, the gaming machine 10 arouses the viewer's inquiring mind by displaying different display modes of the effect display element 822 at a position where observation is difficult by a normal observer (observer v1). Further, the gaming machine 10 may display the effect display element 825a at a position hidden in the accessory 810 instead of the accessory 809. Further, the gaming machine 10 may display the effect display element 825a at a position hidden in the accessory 810 in addition to the accessory 809. Further, when the gaming machine 10 displays the effect display element 825, the gaming machine 10 may display a notification element 825b for notifying that the effect display element 825 is being displayed.

  Next, a modification of the positional relationship between the display surface of the display device 40 and the accessory 809 will be described with reference to FIG. FIG. 148 is a diagram illustrating an example of the positional relationship between the display surface of the display device according to the modification of the fourth embodiment and the movable accessory.

  The gaming machine 10 includes a movable accessory 809 that can change the size of the gap with the display surface 820. The gaming machine 10 can change the size of the gap between the movable accessory 809 and the display surface 820 by operating the movable accessory 809 in accordance with the gaming state or in connection with the game effect.

  A movable accessory 809 shown in FIG. 148 (1) has a gap w2 between it and the display surface 820. The normal observer v1 can observe the first observation region R1 on the display surface 820, but cannot observe the second observation region R2 due to the interference of the movable accessory 809. An observer v2 who looks down on the lower direction of the display area 800 can also observe the first observation area R1 on the display surface 820, but is movable because the gap w2 is not sufficiently large (narrow). The accessory 809 cannot interfere with the observation of the second observation region R2.

  A movable accessory 809 shown in FIG. 148 (2) has a gap w3 between it and the display surface 820. The normal observer v1 can observe the first observation region R1 on the display surface 820, but cannot observe the second observation region R2 due to the interference of the movable accessory 809. In addition, the observer v2 who looks down on the downward direction of the display area 800 can observe the first observation area R1 on the display surface 820, and the gap w2 has a sufficient size (wide), so that the movable accessory It is possible to observe the second observation region R2 without interference with 809.

  Thus, the gaming machine 10 can change the observation ease of the second observation region R2 by operating the movable accessory 809. That is, the gaming machine 10 makes it difficult to observe the second observation region R2 by reducing the gap between the movable accessory 809 and the display surface 820, and observes the second observation region R2 by increasing the gap. make it easier. Therefore, the gaming machine 10 can control the visibility of the effect display element displayed in the second observation region R2 according to the operation state of the movable accessory 809. Thereby, the gaming machine 10 can improve the interest by the game effect in which the operation state of the movable accessory 809 and the display of the effect display element are linked.

The gaming machine 10 of the above-described fourth embodiment (including the modification) has the following characteristics in one aspect.
(1) The gaming machine 10 includes a display device (display device 41), an accessory (intermediate 809) that interferes with a display area of the display device, and a control unit (effect control device 300) that displays an effect display element on the display device. ). The control unit includes a first observation region (first observation region R1) that can be observed from an observer (observer v1) observing from the first position and an observer (observer v2) observing from the second position in the display region. ) In the first effect state (FIG. 146 (1)) in which the effect display element (effect display element 822) is displayed, and it is difficult to observe from the observer observing from the first position in the display area, and observation from the second position. The second effect state (FIG. 146 (2)) in which the effect display element (effect display element 823) is displayed in the second observation region (second observation region R2) that is easy to observe from the observer who performs the switching control.

[Fifth Embodiment]
Next, a gaming machine 10 according to a fifth embodiment (including modifications) will be described with reference to FIGS. 149 to 155. The gaming machine 10 shown in the fifth embodiment has a large symbol group and a small symbol group as two sets of decorative symbols, and can display the large symbol group in two modes, a normal symbol and a chance symbol. The gaming machine 10 of the fifth embodiment blocks a symbol that is variably displayed by a chance display (alternative element) included in the chance symbol. First, a normal symbol and a chance symbol in the large symbol group will be described with reference to FIG. FIG. 149 is a diagram illustrating an example of a symbol arrangement of a large symbol group according to the fifth embodiment.

  The normal symbols in the large symbol group include symbols 830, 831, 832, 833, and 834 in the symbol array. The symbols 830, 831, 832, 833, and 834 can be distinguished from other symbols by different display modes. The symbols 830, 831, 832, 833, and 834 are discriminated by a graphic element 836 having a distinctiveness as a symbol by a graphic (for example, a character) and a character (for example, a number) on a disc-shaped base 835 that is the outer shape of the symbol. And a character element 837 having.

  The chance symbols in the large symbol group include symbols 840, 841, 842, 843, and 844 in the symbol array. The symbols 840, 841, 842, 843, and 844 can be distinguished from other symbols by different display modes. The symbols 840, 841, 842, 843, and 844 are provided on a disk-shaped base 835 that is the outer shape of the symbol, a graphic element 836 having a distinctiveness as a symbol by a graphic (for example, a character), an alternative element 845, and a concealing element 846.

  The substitute element 845 is a display element that substitutes for the character element 837 included in the symbols 830, 831, 832, 833, and 834. The substitute element 845 has a discriminating power that allows the symbols 840, 841, 842, 843, and 844 to be regarded as the same symbol. Have. That is, the symbols 840, 841, 842, 843, and 844 have the discriminating power of the character element 837 while retaining the discriminating power of the graphic element 836 out of the discriminating power of the symbols 830, 831, 832, 833, and 834. It is lost and replaced with the discriminating power of the substitute element 845. The symbols 840, 841, 842, 843, and 844 all function as almighty symbols because they display the alternative elements 845 in the same display mode (for example, “chance !!!!”). The substitute element 845 only needs to be displayed in place of the character element 837, and may take a form such as replacement, overwriting, or pasting. The concealment element 846 conceals the character element 837. Thus, the gaming machine 10 reliably hides the character element 837 while expanding the degree of freedom of the display mode (size, shape, etc.) of the substitute element 845, and the discriminating power of the substitute element 845 increases the discriminating power of the character element 837. Can be substituted.

  Next, display effects of the gaming machine 10 according to the fifth embodiment will be described with reference to FIGS. 150 to 154. FIG. 150 is a diagram illustrating an example of an effect flow according to the fifth embodiment. FIG. 151 is a diagram illustrating an example (part 1) of a screen displayed by the display device according to the fifth embodiment. FIG. 152 is a diagram illustrating an example (part 2) of a screen displayed by the display device according to the fifth embodiment. FIG. 153 is a diagram illustrating an example (No. 3) of a screen displayed by the display device of the fifth embodiment. FIG. 154 is a diagram illustrating an example (No. 4) of a screen displayed by the display device of the fifth embodiment.

  [Production Flow F130] The gaming machine 10 stops and displays the symbols before the start of the change in the change display game. The screen 850 shown in FIG. 151 (F130) includes a large symbol group 851, a small symbol group 852, a special figure 1 hold number display 853, a special figure 2 hold number display 854, a hold display 855, and a hold digest display 856. Is included in the display content.

  Screen 850 shows a state where large symbol group 851 and small symbol group 852 are stopped and displayed. The large symbol group 851 includes an upper right symbol 851a, a lower left symbol 851b, an upper left symbol 851c, a lower right symbol 851d, and a central symbol 851e. The large symbol group 851 is defined as a first effective line that forms a symbol combination that hits a left-downward diagonal line formed by the upper right symbol 851a, the lower left symbol 851b, and the central symbol 851e. In addition, the large symbol group 851 is a second effective line that forms a symbol combination that hits a left upward diagonal line formed by the upper left symbol 851c, the lower right symbol 851d, and the central symbol 851e.

  At this time, the hold-up display 856 indicates that the special figure fluctuation display game is not in the fluctuation display state by a blank display, and the hold display 855 indicates that the total hold memory number of the special figure 1 game and the special figure 2 game is “8”. It shows that there is. The total holding memory number “8” indicated by the holding display 855 is the holding number “4” of the special figure 1 game indicated by the special figure 1 holding number display 853 and the holding of the special figure 2 game indicated by the special figure 2 holding number display 854. This is the total number with the storage number “4”. When the gaming machine 10 starts the symbol variation, the game machine 10 proceeds to the effect flow F131.

  [Production flow F131] The gaming machine 10 starts variable display. A screen 858 shown in FIG. 151 (F131) indicates that the large symbol group 851 and the small symbol group 852 have started to be displayed in a variable manner. For example, the large symbol group 851 displays a variation by rotating the vertical axis in the counterclockwise direction, and the small symbol group 852 displays a variation by vertically scrolling each symbol from the upward direction to the downward direction. At this time, the gaming machine 10 sets the large symbol group 851 in a semi-transparent state, thereby improving the visibility of the background display over the visibility of the large symbol group 851. On the other hand, the gaming machine 10 ensures the visibility prioritizing the background display without making the small symbol group 852 translucent.

  Further, the special figure 2 hold number display 854 displays the number of reserved memories of the special figure 2 game reduced by one, and the hold display 855 displays the number of reserved memories of the special figure variable display game reduced by one. . The reserved digest display 856 indicates that the special figure variation display game is in the variation display state. The gaming machine 10 proceeds to the production flow F132.

  [Production Flow F132] The gaming machine 10 stops the change in the first stage (1st step). In the first stage of variable stop, the upper right symbol 851a and the lower left symbol 851b forming the first effective line in the large symbol group 851 are stopped, and the presence or absence of reach on the first effective line is produced. In the screen 860 shown in FIG. 151 (F132), since the upper right symbol 851a and the lower left symbol 851b are different symbols, the occurrence of reach in the first effective line is denied. When the gaming machine 10 replaces the upper right symbol 851a and the lower left symbol 851b with a chance symbol, the game machine 10 proceeds to the production flow F133, and when the game machine 10 derives “displacement” without replacing the upper right symbol 851a and the lower left symbol 851b with a chance symbol. Proceed to production flow F143. In addition, description is abbreviate | omitted about the case where "hit" is derived | led-out, without replacing the upper right symbol 851a and the lower left symbol 851b with a chance symbol.

  [Production Flow F133] The gaming machine 10 substitutes the chance symbol for the upper right symbol 851a and the lower left symbol 851b. In the screen 862 shown in FIG. 151 (F133), the substitute element 863 is stuck on the upper right symbol 851a, and the substitute element 864 is stuck on the lower left symbol 851b. The gaming machine 10 proceeds to the production flow F134.

  [Production Flow F134] The gaming machine 10 stops the change in the second stage (2nd step). The second-stage fluctuation stop stops the lower right symbol 851d forming the second effective line in the large symbol group 851. A screen 866 shown in FIG. 152 (F134) waits for the upper left symbol 851c to stop, and produces a wait for reach on the second effective line. The gaming machine 10 proceeds to the effect flow F135 when the lower right symbol 851d is replaced with the chance symbol, and proceeds to the effect flow F143 when the "lower" is derived without replacing the lower right symbol 851d with the chance symbol. Note that the description of the case where “hit” is derived without replacing the lower right symbol 851d with the chance symbol will be omitted.

  [Direction Flow F135] The gaming machine 10 substitutes the chance symbol for the lower right symbol 851d. A screen 868 shown in FIG. 152 (F135) shows a state in which an alternative element 869 is attached to the lower right symbol 851d, and the three symbols of the upper right symbol 851a, the lower left symbol 851b, and the lower right symbol 851d are substituted with the chance symbol. Note that the gaming machine 10 denies the occurrence of reach on the second active line without waiting for the stop of the upper left symbol 851c by attaching the substitute element 869 to the lower right symbol 851d. The gaming machine 10 proceeds to the production flow F136.

  [Production Flow F136] The gaming machine 10 stops the change in the third stage (3rd step). The third stage of variable stop stops the upper left symbol 851c forming the second effective line in the large symbol group 851. The screen 870 shown in FIG. 152 (F136) produces a chance symbol substitution waiting for the upper left symbol 851c. The gaming machine 10 proceeds to the effect flow F137 when the upper left symbol 851c is replaced with the chance symbol, and proceeds to the effect flow F143 when the “upper” is derived without replacing the upper left symbol 851c with the chance symbol.

  [Production Flow F137] The gaming machine 10 substitutes the chance symbol for the upper left symbol 851c. In the screen 872 shown in FIG. 152 (F137), an alternative element 873 is attached to the upper left symbol 851c, and the four symbols of the upper right symbol 851a, the lower left symbol 851b, the lower right symbol 851d, and the upper left symbol 851c are replaced with the chance symbol. Indicates. The screen 872 shows the occurrence of reach of an all-chance symbol in which the occurrence of reach by the first effective line and the second effective line is denied, but the central symbol 851e serving as the final stop symbol is replaced with a chance symbol. The gaming machine 10 proceeds to the production flow F138.

  [Direction Flow F138] The gaming machine 10 performs a chance symbol shielding fluctuation 1 corresponding to the preceding stage of reach fluctuation of the all chance symbol. A screen 874 shown in FIG. 153 (F138) shows a state in which the success or failure of pasting the substitute element 875 to the central symbol 851e is produced. The substitute element 875 shown on the screen 874 is enlarged and displayed so as to hide the entire central symbol 851e. At this time, the gaming machine 10 can continue the variable display of the central symbol 851e hidden in the enlarged display of the substitute element 875. The gaming machine 10 proceeds to the production flow F139.

  [Production Flow F139] The gaming machine 10 performs the chance symbol shielding fluctuation 2 corresponding to the reach fluctuation middle stage of the all chance symbol. A screen 876 shown in FIG. 153 (F139) shows a state in which the success or failure of pasting the substitute element 875 to the central symbol 851e is produced. An alternative element 875 shown on the screen 876 reduces the enlargement ratio of the enlarged display that was intended to hide the entire central symbol 851e. At this time, the gaming machine 10 causes a part of the central symbol 851e to be variably displayed to face the back surface of the substitute element 875 being enlarged. The gaming machine 10 proceeds to the production flow F140.

  [Production Flow F140] The gaming machine 10 performs the chance symbol shielding variation 3 corresponding to the reach variation stage of the all chance symbol. A screen 878 shown in FIG. 153 (F140) shows a state in which the success or failure of pasting the substitute element 875 to the central symbol 851e is produced. The central symbol 851e shown on the screen 878 is stopped and displayed while waiting for the pasting of the substitute element 875. At this time, the gaming machine 10 causes a part of the central symbol 851e to be stopped and displayed to face the back surface of the alternative element 875. Note that the gaming machine 10 may notify the success rate of application of the substitute element 875 by the stop display mode of the central symbol 851e facing the back surface of the substitute element 875 or the variable display mode before the stop display. Further, the gaming machine 10 may notify the success rate of the application of the substitute element 875 according to the application mode of the substitute element 875 (for example, the color and size of the substitute element 875, rotation, movement, etc.). The gaming machine 10 proceeds to the effect flow F141 when pasting of the substitute element 875 is successful, and proceeds to the effect flow F143 when pasting of the substitute element 875 fails.

  [Production Flow F141] The gaming machine 10 displays an all chance symbol. A screen 879 shown in FIG. 153 (F141) shows a state where alternative elements are attached to all symbols of the large symbol group 851. The gaming machine 10 proceeds to the production flow F142.

  [Production flow F142] The gaming machine 10 displays a jackpot as a result of the variable display. A screen 880 shown in FIG. 154 (F142) shows a state where the large symbol group 851 is not displayed and the small symbol group 852 is stopped and displayed in a symbol combination manner corresponding to the winning combination. Further, the screen 880 displays a variable display result guidance display 881 and a character 882. The fluctuation display result guidance display 881 and the character 882 guide that a win (for example, big hit) is derived as a result of the special figure fluctuation display game. Note that the screen 880 displays a special figure 1 hold number display 853 and a special figure 2 hold number display 854, but it is not triggered by the fact that the small symbol group 852 has stopped and displayed in the symbol combination mode corresponding to the win. It is good also as a display.

Note that the gaming machine 10 has been shown to be a big hit by displaying all-chance symbols, but a specific gaming state such as a latent probability change or a small hit may be derived.
[Production Flow F143] The gaming machine 10 displays “out” as a result of the variable display. A screen 884 shown in FIG. 154 (F143) shows a state in which the large symbol group 851 and the small symbol group 852 are stopped and displayed in a “displacement” manner. Note that the gaming machine 10 may stop and display the symbol substituted with the chance symbol, or may display the symbol substituted with the chance symbol after returning it to the original (normal symbol).

  Such a gaming machine 10 can display a symbol combination mode corresponding to a win by substituting each symbol with an alternative element, regardless of the stop mode of each symbol in the large symbol group 851. That is, the gaming machine 10 can easily change the variation display mode corresponding to the loss to the variation display mode corresponding to the big hit by displaying the alternative elements. Therefore, the gaming machine 10 can realize various variable display modes without increasing the processing load for diversifying the variable display modes.

  Note that the gaming machine 10 is in charge of special jackpot notifications such as accuracy, as described in the second embodiment, and the chance symbol described in the fifth embodiment is in charge of normal jackpot notifications. May be. Thereby, the gaming machine 10 can make the player easily distinguish between special big hits such as accuracy and normal big hits.

Next, a modified example of the screen displayed by the display device 41 will be described with reference to FIG. FIG. 155 is a diagram illustrating a modification of the screen displayed by the display device of the fifth embodiment.
The screen 886 shown in FIG. 155 (1) has an alternative element 887 attached to the upper right design 851a, an alternative element 888 attached to the lower left design 851b, and an alternative element 889 attached to the upper left design 851c in the large symbol group 851. The state where the alternative element 890 is affixed to the lower right design 851d is shown. A screen 886 shows a state in which the central symbol 851e of the large symbol group 851 is still being variably displayed.

  The substitute element 887 displays the characters “Fever !!!!”, the substitute element 888 displays the characters “???”, the substitute element 889 displays the characters “Leach”, and the substitute element 890 displays the characters “Chance! ! ”Is displayed. As described above, the gaming machine 10 may display a substitute element with a different character for each substitute element.

  The screen 892 shown in FIG. 155 (2) has an alternative element 893 attached to the upper right symbol 851a, an alternative element 894 attached to the lower left symbol 851b, and an alternative element 895 attached to the upper left symbol 851c in the large symbol group 851. The state where the alternative element 896 is affixed to the lower right design 851d is shown. A screen 892 shows a state in which the central symbol 851e of the large symbol group 851 is still being displayed in a variable manner.

  The alternative element 893 and the alternative element 894 display the character “chance !!” in the standard size, and the alternative element 895 and the alternative element 896 display the character “chance !!!!” in the enlarged size. As described above, the gaming machine 10 may display the substitute element with a different size for each substitute element. Further, the gaming machine 10 may notify the possibility of deriving a specific variation display result by the size, number, and combination of sizes of alternative elements.

  The screen 898 shown in FIG. 155 (3) has an alternative element 899 attached to the upper right symbol 851a, an alternative element 900 attached to the lower left symbol 851b, and an alternative element 901 attached to the upper left symbol 851c in the large symbol group 851. The state where the alternative element 902 is affixed to the lower right design 851d is shown. A screen 898 shows a state in which the central symbol 851e of the large symbol group 851 is still being displayed in a variable manner.

  The alternative element 899 and the alternative element 900 display the character “chance !!” in the normal position (horizontal orientation), and the alternative element 901 and alternative element 902 display the character “chance !!!!” in the non-normal position (with inclination). Is displayed. As described above, the gaming machine 10 may display the substitute element at a different position or orientation for each substitute element. Further, the gaming machine 10 may notify the possibility of deriving a specific variation display result based on the position and inclination of the substitute element.

  A screen 904 shown in FIG. 155 (4) has an alternative element 905 attached to the upper right symbol 851a, an alternative element 906 attached to the lower left symbol 851b, and alternative elements 907 and 908 included in the upper left symbol 851c. The state where the alternative elements 909, 910, and 911 are attached to the lower right symbol 851d is shown. A screen 904 shows a state in which the central symbol 851e in the large symbol group 851 is still being variably displayed.

  The upper right symbol 851a and the lower left symbol 851b each display one alternative element, the upper left symbol 851c displays two alternative elements, and the lower right symbol 851d displays three alternative elements. In this way, the gaming machine 10 may display a different number of alternative elements for each symbol constituting the large symbol group 851.

  Further, the gaming machine 10 may notify the derivation possibility (reliability) of a specific variation display result according to the display mode (character content, size, position, orientation, number, etc.) of the alternative element. In addition, the gaming machine 10 may determine the display mode of the alternative elements in relation to the stop order of symbols constituting the large symbol group 851. According to this, the gaming machine 10 can perform a notice notification (for example, a step-up notice or the like) using alternative elements according to the stop order of the symbols constituting the large symbol group 851.

[Sixth Embodiment]
Next, the gaming machine 10 of the sixth embodiment (including modifications) will be described with reference to FIGS. 156 to 160. The gaming machine 10 of the sixth embodiment has a large symbol group and a small symbol group as two sets of decorative symbols. The large symbol group includes character symbols and non-character symbols. The gaming machine 10 according to the sixth embodiment shields the symbol that is being variably displayed by a character (graphic element) included in the character symbol. First, the character design and non-character design in the large design group will be described with reference to FIG. FIG. 156 is a diagram illustrating an example of a symbol arrangement of a large symbol group according to the sixth embodiment.

  The character design and the non-character design in the large symbol group constitute the same symbol arrangement. The large symbol group includes symbols 920, 921, 922, 923, 924, 925, and 926 in the symbol array, of which symbols 920, 921, 922, 923, and 924 correspond to character symbols, and symbols 925 and 926 are non-character characters. It corresponds to a design.

  The gaming machine 10 derives a jackpot based on the combination of the same character symbols, and also derives a jackpot when all symbols are character symbols even if the symbols are different, that is, when a non-character symbol is not included in the symbol combinations. . Further, the gaming machine 10 derives a jackpot by combining the same symbols for a part of the non-character symbols, but does not derive a jackpot by combining the same symbols for the remainder of the non-character symbols. Further, the gaming machine 10 does not derive a big hit even if all the symbols become non-character symbols having different symbols.

  The symbols 920, 921, 922, 923, 924, 925, and 926 are distinguishable from other character symbols and non-character symbols by different display modes. Each of the symbols 920, 921, 922, 923, 924, 925, and 926 is provided with a graphic element 928 having a distinctiveness as a symbol by a graphic (for example, a character) on a rectangular base 927 that is the outer shape of the symbol.

  Character designs (designs 920, 921, 922, 923, and 924) display people (for example, boys and girls), animals (for example, tigers and lions), objects (for example, rockets), and the like as graphic elements 928. Non-character symbols 925 and 926 display characters (for example, “S”), pictograms (for example, “heart mark”), and the like as graphic elements 928. The non-character symbol 925 is a symbol that can derive a big hit by the combination of the same symbols, and the non-character symbol 926 is a symbol (blank symbol) that cannot derive the big hit by the combination of the same symbols.

  Next, display of a large symbol group on the display device will be described with reference to FIG. FIG. 157 is a diagram illustrating an example of display of a large symbol group in the display device according to the sixth embodiment. The display device 41 displays the large symbol group 930 with three-digit symbols arranged in a horizontal row. The display device 41 displays three cube-shaped symbol displays 931L, 931C, and 931R in a horizontal row. The symbol display bodies 931L, 931C, and 931R are vertically rotated by a rotation axis that penetrates the side surfaces, and the symbols 920, 921, 922, 923, 924, 925, and 926 are displayed on the respective surfaces that appear during the rotation. The gaming machine 10 performs a change display of the large symbol group by sequentially switching the symbols 920, 921, 922, 923, 924, 925, and 926 displayed on each surface of the symbol display body.

  The symbol display bodies 931L, 931C, 931R include stop symbol display surfaces 932L, 932C, 932R and next symbol display surfaces 933L, 933C, 933R. The stop symbol display surfaces 932L, 932C, and 932R are surfaces that display a stop symbol when the stop display is performed, and the next symbol display surfaces 933L, 933C, and 933R are the symbols displayed on the stop symbol display surfaces 932L, 932C, and 932R. This is the surface that displays the next symbol. The symbol display bodies 931L, 931C, and 931R switch the next symbol display surfaces 933L, 933C, and 933R, which face the front due to rotational fluctuation, to the stop symbol display surfaces 932L, 932C, and 932R, and the newly displayed surfaces are the next symbol display surfaces. 933L, 933C, and 933R. The stop symbol display surfaces 932L, 932C, and 932R and the next symbol display surfaces 933L, 933C, and 933R display any one of the symbols 920, 921, 922, 923, 924, 925, and 926.

  For example, the symbol display body 931L displays the symbol 926 on the stop symbol display surface 932L, and displays the symbol 925 on the next symbol display surface 933L. The symbol display body 931C displays the symbol 920 on the stop symbol display surface 932C, and displays the symbol 926 on the next symbol display surface 933C. The symbol display body 931R displays the symbol 925 on the stop symbol display surface 932R, and displays the symbol 921 on the next symbol display surface 933L. At this time, the next symbol display surfaces 933L, 933C, and 933R guide the symbol type by the amount of protrusion from the display surface. The symbol 925 displayed on the next symbol display surface 933L protrudes from the next symbol display surface 933L by a height h, and the symbol 926 displayed on the next symbol display surface 933C is depressed by a depth d from the next symbol display surface 933C. (Ie, projecting by a height “−d”). As a result, the gaming machine 10 guides the symbols that can derive the jackpot in the non-character symbols and the symbols that cannot derive the jackpot easily. In addition, the gaming machine 10 may guide the symbol type by the amount of protrusion from the display surface even in the character symbol. Further, the gaming machine 10 may notify the expected value of the symbol stop or the expected value for the derived result instead of guiding the symbol type by the protruding amount from the display surface.

  Next, display effects of the gaming machine 10 according to the sixth embodiment will be described with reference to FIGS. FIG. 158 is a diagram illustrating an example of the effect flow according to the sixth embodiment. FIG. 159 is a diagram illustrating an example (No. 1) of a screen displayed by the display device of the sixth embodiment. FIG. 160 is a diagram illustrating an example (No. 2) of a screen displayed by the display device according to the sixth embodiment.

  [Production Flow F150] The gaming machine 10 stops and displays the symbols before the start of the change in the change display game. A screen 950 shown in FIG. 159 (F150) includes a large symbol group 930, a small symbol group 952, a special figure 1 hold number display 953, a special figure 2 hold number display 954, a hold display 955, and a hold digest display 956. Is included in the display content.

  Screen 950 shows a state where large symbol group 930 and small symbol group 952 are stopped and displayed. The large symbol group 930 includes a symbol display body 931L (left symbol), a symbol display member 931C (middle symbol), and a symbol display member 931R (right symbol). In the large symbol group 930, the horizontal line formed by the three symbols is an effective line that forms a symbol combination as a hit.

  At this time, the hold-up display 956 indicates that the special figure fluctuation display game is not in the fluctuation display state by blank display, and the hold display 955 indicates that the total hold memory number of the special figure 1 game and the special figure 2 game is “8”. Indicates that there is. The total holding memory number “8” indicated by the holding display 955 is the holding number “4” of the special figure 1 game indicated by the special figure 1 holding number display 953 and the holding of the special figure 2 game indicated by the special figure 2 holding number display 954. This is the total number with the storage number “4”. When the gaming machine 10 starts the symbol variation, the game machine 10 proceeds to the effect flow F151.

  [Production flow F151] The gaming machine 10 starts variable display. A screen 958 shown in FIG. 159 (F151) indicates that the large symbol group 930 and the small symbol group 952 have started the variable display. For example, in the large symbol group 930, each symbol is displayed in a variable manner by rotating the vertical axis in the vertical direction, and in the small symbol group 952, each symbol is displayed in a variable manner by vertically scrolling from above to below. At this time, the gaming machine 10 sets the large symbol group 930 to be in a semi-transparent state so that the visibility of the background display is higher than the visibility of the large symbol group 930. On the other hand, the gaming machine 10 ensures the visibility prioritizing the background display without making the small symbol group 952 translucent.

  In addition, the special figure 2 hold number display 954 displays the special memory of the special figure 2 game by decrementing it by one, and the hold display 955 displays the special memory of the special figure variable display game by decrementing by one. . The reserved digest display 956 indicates that the special figure variation display game is in the variation display state. The gaming machine 10 proceeds to the production flow F152 when it develops to reach, and proceeds to the production flow F157 when the game machine 10 becomes “out of” without developing to reach.

  [Production Flow F152] The gaming machine 10 develops to reach. In the screen 960 shown in FIG. 159 (F152), the symbol display 931L displays the character symbol (symbol 920), the symbol display 931R displays the character symbol (symbol 922), and the symbol display member 931C rotates to change. The state during display is shown. That is, screen 960 shows the reach state of the symbol combination (all character symbols) in which all symbols become character symbols when symbol display 931C stops and displays character symbols. The gaming machine 10 proceeds to the production flow F153.

  [Direction Flow F153] The gaming machine 10 performs the character symbol shielding fluctuation 1 corresponding to the preceding stage of reach variation of the all character symbols. A screen 962 shown in FIG. 159 (F153) shows a state in which the success or failure of pasting the character 963 (graphic element 928) to the stop symbol display surface 932C of the symbol display body 931C is produced. A character 963 shown on the screen 962 is enlarged and displayed so as to hide the entire symbol display body 931C. At this time, the gaming machine 10 can continue the variable display of the symbol display body 931 </ b> C hidden in the enlarged character 963. Note that the gaming machine 10 may display the character 963 in a semi-transparent state in order to clearly indicate that the symbol display body 931C is in a variable display. Thereby, the gaming machine 10 can produce success / failure of pasting of the character 963 on the stop symbol display surface 932C while clearly indicating that the symbol display body 931C is in a variable display. The gaming machine 10 proceeds to the production flow F154.

  [Production Flow F154] The gaming machine 10 performs the character symbol shielding fluctuation 2 corresponding to the latter stage of reach variation of the all character symbols. A screen 964 shown in FIG. 160 (F154) shows a state in which the success or failure of the application of the character 963 to the stop symbol display surface 932C of the symbol display body 931C is produced. The symbol display body 931C shown on the screen 962 shows a state of waiting for the successful pasting of the character 963 on the stop symbol display surface 932C while displaying the variation. The character 963 is gradually released from the enlarged display, and a part of the symbol display body 931C faces from the back side.

  Note that the gaming machine 10 may notify the success rate of the application of the character 963 by the variable display mode of the symbol display body 931C facing the back of the character 963. Further, the gaming machine 10 may notify the success rate of application of the character 963 according to the application mode of the character 963 (for example, the color and size of the character 963, rotation, pulsation, and the like). The gaming machine 10 proceeds to the effect flow F155 when the pasting of the character 963 is successful, and proceeds to the effect flow F157 when the pasting of the character 963 fails.

  [Production Flow F155] The gaming machine 10 displays an all character symbol. A screen 966 shown in FIG. 160 (F155) shows that all symbols in the large symbol group 930 are character symbols. Since the character 963 attached to the symbol display body 931C overwrites the stop display (graphic element 928) of the symbol display body 931C, it functions as an alternative graphic element that replaces the stopped graphic element. The gaming machine 10 proceeds to the production flow F156.

  [Production flow F156] The gaming machine 10 displays a win (big hit) as a result of the variable display. A screen 968 shown in FIG. 160 (F156) shows a state in which the large symbol group 930 is not displayed and the small symbol group 952 is stopped and displayed in a symbol combination manner corresponding to the winning combination. The screen 968 displays a variable display result guidance display 969 and a character 970. The fluctuation display result guidance display 969 and the character 970 guide that a win (for example, a big hit) has been derived as a result of the special figure fluctuation display game. Note that the screen 968 displays a special figure 1 hold number display 953 and a special figure 2 hold number display 954, but it is not triggered by the fact that the small symbol group 952 has stopped and displayed in the symbol combination mode corresponding to the win. It is good also as a display.

Note that the gaming machine 10 has been shown to be a big hit by displaying all character symbols, but a specific gaming state such as a latent probability change or a small hit may be derived.
[Production Flow F157] The gaming machine 10 displays “out” as a result of the variable display. A screen 972 shown in FIG. 160 (F157) shows a state in which the large symbol group 930 and the small symbol group 952 are stopped and displayed in the “out” manner. For example, the gaming machine 10 displays a blank symbol 926 (see FIG. 156), which is a non-character symbol, on the stop symbol display surface 931C, thereby displaying the “out of” state of the large symbol group 930.

  Such a gaming machine 10 can display the symbol combination mode corresponding to the winning by overwriting the stop symbol display surface 931C with the character 963 regardless of the stop mode of the stop symbol display surface 931C of the large symbol group 930. That is, the gaming machine 10 can easily change to a variation display mode corresponding to a big hit by overwriting the variation display mode corresponding to the loss with the character 970. Therefore, the gaming machine 10 can realize various variable display modes without increasing the processing load for diversifying the variable display modes.

  Note that the gaming machine 10 is in charge of special jackpot notifications such as the accuracy of a special symbol as described in the second embodiment, and the character symbol described in the sixth embodiment is in charge of a normal jackpot notification. May be. Thereby, the gaming machine 10 can make the player easily distinguish between special big hits such as accuracy and normal big hits.

The gaming machine 10 of the fifth embodiment (including the modifications) and the sixth embodiment described above has the following characteristics in one aspect.
(1) The gaming machine 10 includes a display device (display device 41) and control means (game control device 100, effect control device 300). When the identification information (large symbol group 851, 930) displays the first identification element (character element 837, graphic element 928) in a variable manner, the control means changes the first identification element to the second identification element (alternative A specific display result (almighty symbol: all chance symbol, all character symbol) is derived by substituting with the element 845 (alternative graphic element).

(2) The control means of (1) hides the first identification element and displays the second identification element.
(3) The control means of (2) superimposes the second identification element on the first identification element.

(4) The control means of (2) updates the first identification element with the second identification element.
(5) In the process of substituting the first identification element with the second identification element, the control means of (1) displays the second identification element superimposed on the first identification element being displayed in a variable manner.

(6) The control means of (5) displays the first identification element and the second identification element by displaying the second identification element displayed superimposed on the first identification element in a translucent manner. .
(7) The control means of (1) notifies the possibility of deriving a specific variation display result according to the display mode (character content, size, position, orientation, number, etc.) of the second identification element.

(8) When the identification information is represented by two or more symbol combinations, the control means of (7) determines the display mode of the second identification element in relation to the symbol stop order.
The above processing functions can be realized by a computer. In that case, a program describing the processing contents of the functions that the gaming machine of the embodiment should have is provided. By executing the program on a computer, the above processing functions are realized on the computer. The program describing the processing contents can be recorded on a computer-readable recording medium. Examples of the computer-readable recording medium include a magnetic storage device, an optical disk, a magneto-optical recording medium, and a semiconductor memory. Magnetic storage devices include hard disk devices (HDD), flexible disks (FD), magnetic tapes, and the like. Optical discs include DVD (Digital Versatile Disk), DVD-RAM, CD (Compact Disk) -ROM / RW (ReWritable), and the like. Magneto-optical recording media include MO (Magneto-Optical disk).

  When distributing the program, for example, a portable recording medium such as a DVD or a CD-ROM in which the program is recorded is sold. It is also possible to store the program in a storage device of a server computer and transfer the program from the server computer to another computer via a network.

  The computer that executes the program stores, for example, the program recorded on the portable recording medium or the program transferred from the server computer in its own storage device. Then, the computer reads the program from its own storage device and executes processing according to the program. The computer can also read the program directly from the portable recording medium and execute processing according to the program. In addition, each time a program is transferred from a server computer connected via a network, the computer can sequentially execute processing according to the received program.

  Further, at least a part of the above processing functions can be realized by an electronic circuit such as a DSP (Digital Signal Processor), an ASIC (Application Specific Integrated Circuit), or a PLD (Programmable Logic Device).

  Note that the gaming machine of the present invention is not limited to a pachinko gaming machine as shown in the disclosed embodiment as a gaming machine, for example, other pachinko gaming machines, arrange ball gaming machines, sparrow ball gaming machines, etc. The present invention can be applied to all gaming machines that use the game balls and slot machines that are medals.

  The disclosed embodiments are to be considered in all respects as illustrative and not restrictive. Moreover, you may apply combining each structure of the above-mentioned embodiment and modification. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 10 Game machine 30 Game board 41 Display apparatus 100 Game control apparatus 300 Production control apparatus 830,831,832,833,834 Design (normal design)
835 Base 836 Graphic element 837 Character element 840, 841, 842, 843, 844 Design (chance design)
845,875 Alternative elements

Claims (1)

A display device;
Control means for performing variable display control of identification information in the display device,
The control means includes
When the identification information includes a first identification element and variably displays, the first identification element is replaced with a second identification element to derive a specific display result;
Gaming machine.

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