JP6138099B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine such as a pachislot machine.

  Conventionally, it is detected that a plurality of reels having a plurality of symbols arranged on each surface, a game medal, a coin or the like (hereinafter referred to as “game medium”), and the start lever is operated by the player, A start switch that requests the start of rotation of a plurality of reels and a stop button provided corresponding to each of the plurality of reels are detected by the player, and the stop of rotation of the corresponding reel is requested. A stop switch that outputs a signal, a stepping motor that is provided corresponding to each of the plurality of reels, and that transmits each driving force to each reel, and a stepping motor based on the signals output by the start switch and the stop switch A reel control unit that controls the operation of each reel, and rotates and stops each reel, and the start lever is operated. Is detected, the lottery is performed based on the random number value, and the rotation of the reel is stopped based on the result of the lottery (hereinafter referred to as “internal winning combination”) and the timing at which the stop button is detected. A game machine called a so-called pachislot machine is known.

  As this type of gaming machine, a plurality of game machines including a general game state, a high RT game state in which the winning probability of a re-game actuator is higher than the general game state, and an additional game state in which the number of games in the high RT game state is added Japanese Patent Application Laid-Open No. 2004-133867 proposes a gaming machine that shifts a gaming state in accordance with establishment of a predetermined transition condition between the gaming states.

  In the conventional gaming machine proposed in Patent Document 1, when the gaming state shifts from the high RT gaming state to the additional gaming state, the number of times of adding the number of games in the high RT gaming state is determined by lottery. In the state, the stop operation for winning the winning combination for adding the number of games in the high RT gaming state by the determined number of games is notified, and in the subsequent games, the role for establishing the condition for shifting from the adding gaming state to the high RT gaming state Was informed of the stop operation to win.

JP 2010-233721 A

  However, in the conventional gaming machine described above, when the gaming state shifts to the added gaming state, the number of times of adding the number of games in the high RT gaming state, which is an advantageous gaming state advantageous to the player, is determined. However, there is a problem that the player can only have a monotonous expectation for the game in the added gaming state.

  The present invention has been made to solve such a problem, and an object of the present invention is to provide a gaming machine capable of making a player have various expectations for a game in an added gaming state. .

  In order to achieve the above object, the gaming machine according to the present invention displays a plurality of reels (3L, 3C, 3R) displaying a plurality of symbols and a part of the plurality of symbols displayed on the reels. Means (display windows 4L, 4C, 4R), symbol changing means (stepping motors 51L, 51C, 51R) for changing the symbol by rotating the reel based on establishment of a predetermined start condition, and the predetermined An internal winning combination determining means (main CPU 93) for determining an internal winning combination with a predetermined winning probability from a plurality of winning combinations based on the establishment of the start condition, and provided corresponding to the plurality of reels, and stopping each reel Stop operation detecting means (stop switch 17S) for detecting a stop operation for making the internal winning combination determined by the internal winning combination determining means and the stop operation detecting means Reel stop control means (main CPU 93, stepping motors 51L, 51C, 51R) which stops the fluctuation of the symbol displayed on the symbol display means by stopping the rotation of the reel based on the timing at which the operation is detected. ), And whether or not the symbol change is stopped by the reel stop control means, the winning or non-winning of the combination is determined based on the combination of the symbols stopped on the effective line provided in the symbol display means. A winning determination means (main CPU 93), an image display means (liquid crystal display device 11) for displaying an effect image including a plurality of decorative symbols, and an advantageous gaming state advantageous to the player when a specific condition is satisfied When the game state is transferred to (GG) and the specific transfer condition is satisfied, the existence of the above-mentioned existence over the specified number of unit games (for example, 16 games). A gaming state transition means (sub CPU102) for shifting the gaming state to an additional gaming state (EG) for performing an extra lottery of gaming state, and a combination of predetermined symbols (for example, red) on the symbol display means in the additional gaming state On the condition that (7) is displayed, it is advantageous to the player according to the number of remaining games in the added gaming state (for example, the continuation rate is high according to the number of remaining games). On the condition that the advantageous gaming state is added by the advantageous gaming state adding means (sub CPU 102) for performing the above-mentioned advantageous gaming state adding means, the remaining number of games in the additional gaming state is set as the prescribed unit number of games. An extra game number setting means (sub CPU 102) for setting, and the extra game number setting means satisfies a special condition in the extra game state. And the subtraction of the number of games in the added gaming state is stopped (SEG) over the number of unit games determined by lottery until the advantageous gaming state is added by the advantageous gaming state adding means. Yes.

  With this configuration, the gaming machine according to the present invention not only adds the advantageous gaming state according to the result of each unit game in the added gaming state, but also provides the player with the number of remaining games in the added gaming state. Since the advantageous game state is advantageously added and the remaining number of games in the added game state is returned to the prescribed unit game number, the player can have various expectations for the game in the added game state.

  In addition, the gaming machine according to the present invention maintains the remaining number of games in the added gaming state over the number of unit games determined by lottery until the advantageous gaming state is added when the special condition is satisfied in the added gaming state. As a result, the number of unit games in the added gaming state increases, and the probability that the advantageous gaming state will be added substantially increases. Therefore, the player has more diverse expectations for the game in the added gaming state. Can be held.

  The advantageous game state adding means may add the advantageous game state by lottery when a history of past unit game results satisfies a predetermined condition.

  With this configuration, the gaming machine according to the present invention adds an advantageous gaming state when the history of past unit gaming results satisfies a predetermined condition, regardless of whether the gaming state is in the added gaming state or not. By doing so, it is possible to give the player a greater variety of expectations for the game in the added gaming state.

  Moreover, you may make it further provide the log | history display means (liquid crystal display device 11) which displays the log | history of the result of the said past unit game.

  With this configuration, the gaming machine according to the present invention displays the history of past unit game results, so that even if the player does not memorize past unit game results, the game machine is expected to gain an advantageous gaming state. The degree can be recognized by the player.

  ADVANTAGE OF THE INVENTION According to this invention, the game machine which can make a player have various expectations with respect to the game in an addition game state can be provided.

It is a figure which shows the functional flow of the pachislot machine which concerns on embodiment of this invention. 1 is an overall perspective view showing an external structure of a pachislot machine according to an embodiment of the present invention. 1 is a block diagram showing an electrical configuration of a pachislot machine according to an embodiment of the present invention. It is a block diagram which shows the structure of the main control circuit of the pachislot machine which concerns on embodiment of this invention. It is a block diagram which shows the structure of the sub control circuit of the pachi-slot machine which concerns on embodiment of this invention. It is a figure for demonstrating the signal transmitted to the external device from the external concentration terminal board of the pachislot machine which concerns on embodiment of this invention. It is a state transition diagram of the gaming state in the pachislot machine according to the embodiment of the present invention. It is a state transition diagram of the sub gaming state in the pachislot machine according to the embodiment of the present invention. It is a figure which shows the symbol arrangement | positioning table memorize | stored in main ROM. It is a figure which shows the symbol code table in the pachislot machine which concerns on embodiment of this invention. It is a figure which shows the symbol combination table memorize | stored in main ROM. It is a figure which shows the symbol combination table following FIG. It is a figure which shows the symbol combination table following FIG. It is a figure which shows the combination table classified by flag memorize | stored in main ROM. It is a figure which shows the combination table according to flag following FIG. It is a figure which shows the combination table classified by flag following FIG. It is a figure which shows the internal lottery table (RT0 game state) memorize | stored in main ROM. It is a figure which shows the internal lottery table (RT1 game state) memorize | stored in main ROM. It is a figure which shows the internal lottery table (BB game state) memorize | stored in main ROM. It is a figure which shows the rotation stop initial setting table memorize | stored in main ROM. It is a figure which shows the drawing | rank priority table memorize | stored in main ROM. It is a figure which shows the drawing priority order selection table memorize | stored in main ROM. It is a figure which shows the priority order table memorize | stored in main ROM. It is a figure which shows the internal winning combination storing area allocated to main RAM. It is a figure which shows the display combination storage area allocated to main RAM. It is a figure which shows the symbol code storage area allocated to main RAM. It is a figure which shows the carryover combination storage area allocated to main RAM. It is a figure which shows the game state flag storage area allocated to main RAM. It is a figure which shows the operation | movement stop button storage area allocated to main RAM. It is a figure which shows the pressing order storage area allocated to main RAM. It is a figure which shows the drawing priority order data storage area allocated to main RAM. It is a figure which shows the subflag conversion table referred by subCPU. It is a figure which shows the conversion table classified by subflag state (normally) referred by subCPU. It is a figure which shows the conversion table (in CZ1 and CZ2) classified by subflag state referred by subCPU. It is a figure which shows the conversion table classified by subflag state (in GG) referred by subCPU. It is a figure which shows the conversion table (in CZ3 and CZ4) classified by subflag state referred by subCPU. It is a figure which shows the conversion table (in EG) classified by subflag state referred by subCPU. It is a figure which shows the conversion table classified by subflag state (in SEG) referred by subCPU. It is a figure which shows the conversion table classified by subflag state (in PEG) referred by subCPU. It is a figure which shows the subflag lottery conversion table referred by subCPU. It is a figure which shows the CZ number group lottery table referred by sub CPU. It is a figure which shows the CZ outcome group lottery table referred by sub CPU. It is a figure which shows the CZ output group conversion table referred by sub CPU. FIG. 44 is a diagram showing a CZ output group conversion table following FIG. 43. It is a figure which shows the GG winning time distribution table referred by sub CPU. It is a figure which shows the GG winning distribution lottery table referred by sub CPU. It is a figure which shows the CZHOLD lottery table referred by sub CPU. It is a figure which shows the GG winning rate lottery table after CZHOLD referred by sub CPU. It is a figure which shows the GG winning rate lottery table after CZHOLD following FIG. It is a figure which shows the GG lottery table after CZHOLD referred by sub CPU. It is a figure which shows the rewind lottery table referred by sub CPU. It is a figure which shows the rewinding win distribution table referred by sub CPU. It is a figure which shows the distribution lottery table at the time of the rewinding winning referred by sub CPU. It is a figure which shows the PEG promotion lottery table referred by sub CPU. It is a figure which shows the GG continuation rate lottery table at the time of EG reference referred by sub CPU. It is a figure which shows the SEG addition game number lottery table referred by sub CPU. It is a figure which shows the log | history lottery table referred by sub CPU. It is a figure which shows the log | history lottery table following FIG. It is a flowchart which shows the main control process of the pachislot machine which concerns on embodiment of this invention. 60 is a flowchart showing a power-on process executed in the main control process shown in FIG. 59. 60 is a flowchart showing a medal acceptance / start check process executed in the main control process shown in FIG. 59. 60 is a flowchart showing an internal lottery process executed in the main control process shown in FIG. 59. 63 is a flowchart showing a gaming state flag transition process executed in the internal lottery process shown in FIG. 62. 60 is a flowchart showing a reel stop initial setting process executed in the main control process shown in FIG. 59. FIG. 60 is a flowchart showing a pull-in priority storage process executed in the main control process shown in FIG. 59 and the reel stop control process shown in FIG. 68. FIG. FIG. 66 is a flowchart showing a drawing priority table selection process executed in the drawing priority order storage process shown in FIG. 65. FIG. 69 is a flowchart showing a symbol code storing process executed in the drawing priority order storing process shown in FIG. 65 and the reel stop control process shown in FIG. 68; 60 is a flowchart showing a reel stop control process executed in the main control process shown in FIG. 59. 60 is a flowchart showing a bonus end check process executed in the main control process shown in FIG. 59. 60 is a flowchart showing a bonus operation check process executed in the main control process shown in FIG. 59. It is a flowchart which shows the interruption process by control of the main CPU which comprises the pachislot machine which concerns on embodiment of this invention. 72 is a flowchart showing an input port check process executed in the interrupt process shown in FIG. 71. It is a flowchart which shows the power-on process of the sub CPU which comprises the pachislot machine which concerns on embodiment of this invention. 74 is a flowchart showing a lamp control task activated in the power-on process shown in FIG. 73. 74 is a flowchart showing a sound control task activated in the power-on process shown in FIG. 73. 74 is a flowchart showing a mother task activated by the power-on process shown in FIG. 73. 77 is a flowchart showing a main task executed in the mother task shown in FIG. 76. 77 is a flowchart showing a main board communication task executed in the mother task shown in FIG. 76. FIG. 79 is a flowchart showing command analysis processing executed in the main board communication task shown in FIG. 78. FIG. 77 is a flowchart showing an animation task activated in the mother task shown in FIG. 76. 80 is a flowchart showing effect content determination processing executed in the command analysis processing shown in FIG. 79. It is a flowchart which shows the process at the time of the start command reception performed in the production content determination process shown in FIG. It is a flowchart which shows the lottery pre-processing performed by sub CPU. It is a flowchart which shows the CZ counter process performed by sub CPU. FIG. 85 is a flowchart showing CZ counter processing following FIG. 84. It is a flowchart which shows the process in CZ performed by sub CPU. FIG. 89 is a flowchart showing processing during CZ following FIG. 86. It is a flowchart which shows the reel stop command reception time process performed in the effect content determination process shown in FIG. It is a flowchart which shows the process at the time of 1 stop and 2 stop performed by sub CPU. It is a flowchart which shows the process at the time of 3 stop performed by sub CPU. It is a flowchart which shows the process at the time of 3 stops following FIG. It is a flowchart which shows the process at the time of 3 stops following FIG. It is a flowchart which shows the process in EG performed by sub CPU. FIG. 95 is a flowchart showing processing during EG following FIG. 93. FIG. FIG. 95 is a flowchart showing processing during EG following FIG. 94. FIG. It is a flowchart which shows the process during SEG performed by sub CPU. FIG. 97 is a flowchart showing processing during SEG following FIG. 96. FIG. It is a flowchart which shows the process in PEG performed by sub CPU. FIG. 99 is a flowchart showing an in-PEG process following FIG. 98. FIG. It is a flowchart which shows the process during GG performed by sub CPU. It is a flowchart which shows the common process performed by sub CPU. It is a flowchart which shows the common process following FIG. It is a flowchart which shows the historical information generation process performed by sub CPU. It is a flowchart which shows the log | history information generation process following FIG. 105 is a flowchart showing history information generation processing following FIG. 104. FIG. 106 is a flowchart showing history information generation processing following FIG. 105. FIG. It is a flowchart which shows the common lottery process performed by sub CPU. It is a flowchart which shows the lottery post-process performed by sub CPU. It is a flowchart which shows the CZ starting process performed by sub CPU. It is a flowchart which shows the GG starting process performed by sub CPU. It is a figure for demonstrating the state by which the decoration design displayed on the liquid crystal display device by the sub CPU is held. It is a figure for demonstrating the state in which "mirror" was displayed on the liquid crystal display device by the sub CPU at the time of a 1st stop. It is a figure for demonstrating the state in which "mirror" was displayed on the liquid crystal display device at the time of the 1st and 2nd stop by sub CPU. (A) is a timing chart of various signals including the external signal 2 when the combination relating to GOD1 and GOD2 is displayed on the effective line when the GOD is not in GG, and (b) is the GG according to GOD. It is a timing chart of various signals including the external signal 2 when the combination concerning GOD1 and GOD2 is displayed on the effective line again. It is a schematic diagram of the lamp 19L. It is a figure which shows the CZ1 button stock lottery table referred in the modification of the process in CZ performed by sub CPU. It is a figure which shows the CZ1GG lottery table referred in the modification of the process in CZ performed by sub CPU. It is a figure which shows the CZ1 button counter GG conversion lottery table referred in the modification of the process in CZ performed by sub CPU. It is a flowchart which shows the modification of the process during CZ performed by sub CPU. 119 is a flowchart illustrating a modification of the CZ middle processing following FIG. 119;

  A pachislot machine that is a gaming machine according to an embodiment of the present invention will be described with reference to FIGS. First, a functional flow according to the embodiment of the gaming machine will be described with reference to FIG.

  In the pachislot machine of the present embodiment, medals are used as game media for playing games. In addition to the medals, coins, game balls, game point data, tokens, or the like can be applied as game media.

  When a player inserts a medal and operates the start lever, one value (hereinafter, random number value) is extracted from random numbers in a predetermined numerical range (for example, 0 to 65535).

  The internal winning combination determining means performs lottery based on the extracted random number value and determines the internal winning combination. That is, when the start lever is operated, the internal winning combination determining means determines an internal winning combination with a predetermined winning probability from among a plurality of combinations, assuming that a predetermined start condition is satisfied. The internal winning combination determining means is a main control circuit described later. By determining the internal winning combination, a combination of symbols that permits display along a winning determination line described later is determined. The types of symbol combinations include those related to “winning” in which benefits such as paying out medals, re-games, bonuses, etc. are given to players, and other so-called “loses”. Is provided.

  Further, when the start lever is operated, a plurality of reels are rotated. Thereafter, when the player presses the stop button corresponding to the predetermined reel, the reel stop control means stops the rotation of the corresponding reel based on the internal winning combination and the timing when the stop button is pressed. Control to stop the fluctuation of the symbol. The reel stop control means is responsible for a main control circuit and a stepping motor which will be described later.

  In the pachislot machine, basically, control is performed to stop the rotation of the corresponding reel within a specified time (190 msec or 75 msec) from when the stop button is pressed. In the present embodiment, the number of symbols that move with the rotation of the reel within the specified time is referred to as “the number of sliding symbols”. When the specified time is 190 msec, the maximum number of sliding symbols is set to 4 symbols, and when the specified time is 75 msec, the maximum number of sliding symbols is set to 1 symbol.

  When the internal winning combination allowing the symbol combination display related to winning is determined, the reel stop control means usually displays the symbol combination within the specified time of 190 msec (four symbols) for the winning determination line. The rotation of the reel is stopped so as to display as much as possible. In addition, the reel stop control means uses various specified times corresponding to the gaming state to rotate the reels so that combinations of symbols that are not permitted to be displayed by the internal winning combination are not displayed along the winning determination line. Stop.

  The winning determination means is based on the combination of symbols stopped on the winning determination line based on the fact that the reel stop control means stops the rotation of the plurality of reels and the change in the symbols is stopped. Judge the winning. This winning determination means is carried out by a main control circuit described later. When the winning determination means determines that the winning combination is a prize, a privilege such as a medal payout is given to the player. In a pachislot machine, a series of flows as described above is performed as one game.

  Also, in the pachislot machine, in the series of flows described above, video display performed by an image display device such as a liquid crystal display device, light output performed by various lamps, sound output performed by a speaker, or a combination thereof is used. Various productions are performed.

  When the start lever is operated, an effect random number value (hereinafter referred to as effect random number value) is extracted separately from the random number value used for determining the internal winning combination. When the effect random number value is extracted, the effect content determining means determines, by lottery, what is to be executed this time from among a plurality of types of effect contents associated with the internal winning combination. This effect content determination means is carried out by a sub-control circuit described later.

  When the contents of the effect are determined, the effect executing means executes the corresponding effect in conjunction with each opportunity, such as when the rotation of the reels starts, when the rotation of each reel stops, or when determining whether there is a winning. As described above, in the pachislot machine, the player has an opportunity to know or predict the determined internal winning combination (in other words, a combination of symbols to be aimed at) by executing the production contents associated with the internal winning combination. The player's interest can be improved.

<Pachislot machine structure>
Next, the external structure of the pachislot machine according to the present embodiment will be described with reference to FIG.

[Appearance structure]
FIG. 2 is a perspective view showing the external structure of the pachi-slot machine 1.

  As shown in FIG. 2, the pachi-slot machine 1 includes an exterior body 2. The exterior body 2 has a cabinet 2a as a housing for housing a reel, a circuit board, and the like, and a front door 2b attached to the cabinet 2a so as to be openable and closable. Handles 2c are provided on both side surfaces of the cabinet 2a (only the handle 2c on one side is shown in FIG. 2). The handle 2c is a recess that is put on when the pachislot machine 1 is transported.

  On the back side of the front door 2b, a plurality of (for example, 20) reels 3L, 3C, 3R on which a plurality of (for example, 20) symbols are displayed at predetermined intervals along the circumferential direction are provided. It has been.

  Although not shown, a backlight is provided inside each of the reels 3L, 3C, 3R. The backlight illuminates the symbols of the reels 3L, 3C, and 3R from behind, and corresponds to three symbols that are stopped and displayed on the display window 4 to be described later, for each reel 3L, 3C, and 3R. Three backlights are provided vertically.

  These backlights are also used for lamp effects generated after the reels 3L, 3C, 3R are stopped. A plurality of lamp effects are set in association with the types of small roles, but are forcibly terminated when a predetermined condition is satisfied. In the present embodiment, the predetermined condition corresponds to, for example, when the payout of medals associated with the small role winning is completed, the automatic insertion of medals by the replay winning is completed, or the case where the player cares for medals. To do.

  If the medal insertion into the next game is completed upon completion of the payout, or the start operation of the next game is permitted through automatic insertion or maintenance, the next game will be forcibly terminated by forcibly terminating the effect by the backlight. The display result can be clearly displayed to the player before starting.

  Hereinafter, the reels 3L, 3C, and 3R are referred to as a left reel 3L, a middle reel 3C, and a right reel 3R, respectively. Each reel 3L, 3C, 3R has a reel body formed in a cylindrical shape and a translucent sheet material mounted on the peripheral surface of the reel body. The above-mentioned plural (for example, 20) symbols are drawn on the surface of the aforementioned sheet material.

  The front door 2b includes a door body 9 and a liquid crystal display device 11 as image display means for displaying an image. The door body 9 is attached to the cabinet 2a using a hinge (not shown) so as to be freely opened and closed. The hinge is provided at the left end of the door body 9 when the door body 9 is viewed from the front of the pachi-slot machine 1.

  The liquid crystal display device 11 has a display surface larger than the display window 4 and displays information related to the game, such as an image related to a game effect, a decorative pattern for notification, and a history of past unit game results. It is provided above the display window 4. Thus, the liquid crystal display device 11 constitutes a history display unit. Further, the liquid crystal display device 11 can also display game table information such as customization of gaming machines and gaming history, in addition to performing effects by displaying images.

  The front door 2b has a display window 4 through which the three reels 3L, 3C, and 3R can be visually recognized. The display window 4 includes three left display windows 4L, middle display windows 4C, and right display windows 4R corresponding to the three reels 3L, 3C, 3R.

  These display windows 4L, 4C, and 4R are provided at positions overlapping with the arrangement areas of the three reels 3L, 3C, and 3R when viewed from the front (player side), and in front of the three reels (player side) ). Thereby, the display windows 4L, 4C, 4R can display a part of a plurality of symbols displayed on the reels 3L, 3C, 3R. Therefore, the player can visually recognize the three reels 3L, 3C, 3R provided behind the display window 4 through the display windows 4L, 4C, 4R. The display windows 4L, 4C, 4R constitute symbol display means.

  In the present embodiment, the display windows 4L, 4C, 4R are continuously arranged among a plurality of types of symbols drawn on each reel when the rotation of the corresponding reel provided behind the display window 4L, 4C, 4R is stopped. The size is set so that three symbols can be displayed. That is, in the frame of the display windows 4L, 4C, 4R, the upper, middle, and lower areas are provided for each reel, and one symbol is displayed in each area. In this embodiment, a line connecting the middle stage area of the left reel 3L, the middle stage area of the middle reel 3C, and the middle stage area of the right reel 3R is a winning determination line (also referred to as an effective line) for determining whether or not a prize is won. Define it as 8).

  A pedestal 12 is formed in the center of the door body 9. The pedestal portion 12 is provided with various devices (medal insertion slot 13, MAX bet button 14, 1 bet button 15, start lever 16, stop buttons 17L, 17C, and 17R) to be operated by the player.

  The medal slot 13 is provided for receiving a medal dropped on the pachislot machine 1 from the outside by the player. That is, the medal slot 13 is for a medal to be inserted by the player. The medals inserted from the medal slot 13 are used for one game with a preset number (for example, three) as the upper limit, and the amount exceeding the preset number is deposited inside the pachislot machine 1. (So-called credit function).

  The MAX bet button 14 and the 1 bet button 15 are provided to determine the number of cards used for one game from medals deposited inside the pachislot machine 1. The pedestal portion 12 is provided with a settlement button 18. This checkout button 18 is provided to draw out (discharge) medals deposited inside the pachislot machine 1 to the outside.

  The start lever 16 is for starting the rotation of all the reels (3L, 3C, 3R) in accordance with the player's operation, and constitutes a start operation means.

  The stop buttons 17L, 17C, and 17R are provided in association with the left reel 3L, the middle reel 3C, and the right reel 3R, respectively, and are for stopping the rotation of the corresponding reels according to the player's operation. . These stop buttons 17L, 17C, and 17R constitute stop operation means. Hereinafter, the stop buttons 17L, 17C, and 17R are referred to as a left stop button 17L, a middle stop button 17C, and a right stop button 17R, respectively.

  Further, on the left side of the display window 4, a 7-segment display 28 composed of a 7-segment LED (Light Emitting Diode) is provided. The 7-segment display 28 displays information such as the number of medals to be paid out to the player as a privilege (hereinafter referred to as the number of payouts), the number of medals deposited inside the pachislot machine 1 (hereinafter referred to as the number of credits), and the like. Digital display.

  A GOD button 29 is provided on the right side of the display window 4. The GOD button 29 is pressed by a player in, for example, an effect related to a game, and is used during an effect linked with lamps 19L and 19R described later. It should be noted that the GOD button 29 can be pressed at the time of production other than the above-described production or at the time of production. In addition to the lamps 19L and 19R, the GOD button 29 is also used for a pressing operation for reproducing special sound, for example, in conjunction with the speakers 23L and 23R.

  At the lower part of the door body 9, a medal payout port 21, a medal tray 22, speakers 23L, 23R and the like are provided. The medal payout port 21 guides medals discharged by driving a hopper device 43 described later to the outside. The medal tray 22 stores medals discharged from the medal payout opening 21. In addition, the speakers 23L and 23R output sound such as sound effects and music corresponding to the contents of the production.

  In addition, lamps 19L and 19R that can emit light in a plurality of colors are provided on the left and right sides of the door body 9 with the liquid crystal display device 11 interposed therebetween. The lamps 19L and 19R are configured by an LED group 25 (see FIG. 3) described later. The lamps 19L and 19R are not limited to LEDs, and existing light emitting elements such as organic electroluminescence (organic EL) may be used as long as they can emit at least green, yellow, blue, and red.

<Electric configuration of pachislot machine>
Next, the electrical configuration of the pachislot machine 1 will be described with reference to FIG. FIG. 3 is a block diagram showing an electrical configuration of the pachi-slot machine 1.

  As shown in FIG. 3, the pachi-slot machine 1 has a main control board 41 provided in the cabinet 2a and a sub-control board 42 provided in the front door 2b. The main control board 41 is electrically connected to the reel relay terminal board 51, the setting key switch 52, the cabinet side relay board 53, the door relay terminal board 54, and the power board 44 b of the power supply device 44. ing.

  The reel relay terminal plate 51 is disposed inside the reel body of each reel 3L, 3C, 3R. The reel relay terminal plate 51 is electrically connected to the stepping motors 51L, 51C, 51R of the reels 3L, 3C, 3R, and receives signals output from the main control board 41 to the stepping motors 51L, 51C, 51R. Relay.

  The stepping motors 51L, 51C, 51R change the design by rotating the reels 3L, 3C, 3R based on the establishment of a predetermined start condition, that is, the start lever 16 being operated by the player (start operation). Let The stepping motors 51L, 51C, 51R constitute symbol variation means. The setting key type switch 52 is used when changing the setting of the pachislot machine 1 or when checking the setting of the pachislot machine 1.

  The cabinet-side relay board 53 is electrically connected to an external concentration terminal board 56, a hopper device 43, and a medal auxiliary storage switch 57. The cabinet-side relay board 53 relays signals output from the main control board 41 to the external concentration terminal board 56, the hopper device 43, and the medal auxiliary storage switch 57. That is, the external concentration terminal board 56, the hopper device 43 and the medal auxiliary storage switch 57 are connected to the main control board 41 via the cabinet side relay board 53.

  The external concentration terminal board 56 is attached to the cabinet 2a and is provided to output signals such as a medal insertion signal, a medal payout signal, external signals 1 to 4 and a security signal to the outside of the pachislot machine 1.

  The medal auxiliary storage switch 57 passes through a medal auxiliary storage (not shown). The medal auxiliary storage switch 57 detects whether or not the medal auxiliary storage is full of medals.

  A power switch 44 a is connected to the power board 44 b of the power device 44. The power switch 44a is turned on when supplying necessary power to the pachislot machine 1.

  Connected to the door relay terminal board 54 are a medal sensor 46, a door open / close monitoring switch 61, a BET switch 62, a settlement switch 63, a start switch 64, a stop switch board 65, a game operation display board 66, and a sub relay board 69. . That is, the medal sensor 46, the door open / close monitoring switch 61, the BET switch 62, the settlement switch 63, the start switch 64, the stop switch board 65, the game operation display board 66, and the sub relay board 69 are connected via the door relay terminal board 54. It is connected to the control board 41.

  The medal sensor 46 detects that the medal has passed through a selector (not shown) and outputs the detection result to the main control board 41. The door open / close monitoring switch 61 outputs a security signal for notifying the opening / closing of the front door 2b to the outside of the pachislot machine 1. The BET switch 62 detects that the MAX bet button 14 and the 1 bet button 15 (see FIG. 2) have been pressed by the player, and outputs the detection result to the main control board 41.

  The settlement switch 63 detects that the settlement button 18 has been pressed by the player, and outputs the detection result to the main control board 41. The start switch 64 detects that the start lever 16 has been operated by the player (start operation), and outputs the detection result to the main control board 41.

  The stop switch substrate 65 is a substrate constituting a circuit for stopping the rotating reel and a circuit for displaying the stopable reel by an LED or the like. The stop switch board 65 is provided with stop switches 17S corresponding to the three reels 3L, 3C, 3R. The stop switch 17S detects a stop operation for stopping the rotation of the reels 3L, 3C, 3R, that is, that the stop buttons 17L, 17C, 17R are pressed by the player.

  The game operation display board 66 displays the number of inserted medals on the 7-segment display 28 when accepting insertion of medals, when the three reels 3L, 3C, 3R are rotatable and when replaying. It is a substrate for making it. A 7-segment display 28 and an LED 70 are connected to the game operation display board 66. For example, the LED 70 lights a mark for displaying the start of a game, a mark for performing a replay, and the like.

  The sub relay board 69 relays the wiring connecting the sub control board 42 and the main control board 41. The sub-relay board 69 relays the wiring connecting the sub-control board 42 and a plurality of boards disposed around the sub-control board 42. That is, to the sub relay board 69, the sub control board 42, the sound I / O board 71, the LED board 72, and the 24h door opening / closing monitoring unit 74 are electrically connected.

  The sub control board 42 is connected to the main control board 41 through the door relay terminal board 54 and the sub relay board 69. The sub control board 42 is electrically connected to the sound I / O board 71, the LED board 72, and the 24h door opening / closing monitoring unit 74 via the sub relay board 69.

  The sound I / O board 71 outputs sound to the speakers 23L and 23R. The LED board 72 causes the LED group 25 showing a specific example of the light source to emit light and display a blinking pattern in accordance with the effect executed by the control of the sub control circuit 101 (see FIG. 5).

  The 24h door opening / closing monitoring unit 74 stores a history of opening / closing of the front door 2b. The 24h door opening / closing monitoring unit 74 outputs a signal for displaying an error on the liquid crystal display device 11 to the sub control board 42 (sub control circuit 101) when the front door 2b is opened.

  A ROM cartridge substrate 76, a liquid crystal relay substrate 77, and a GOD button 29 are connected to the sub control substrate 42. The ROM cartridge substrate 76 is a substrate for managing production images (video), sound, light (LED group 25), and communication data. The liquid crystal relay substrate 77 is a substrate that relays the wiring connecting the sub control substrate 42 and the liquid crystal display device 11.

<Main control circuit>
Next, the main control circuit 91 constituted by the main control board 41 will be described with reference to FIG. FIG. 4 is a block diagram illustrating a configuration example of the main control circuit 91 of the pachislot machine 1.

  As shown in FIG. 4, a main control circuit 91 as a main control unit has a microcomputer 92 installed on the main control board 41 as a main component, and controls the progress of the game. The microcomputer 92 includes a main CPU 93, a main ROM 94, and a main RAM 95.

  The main ROM 94 stores a control program executed by the main CPU 93, a data table, data for transmitting various control commands (command signals) to the sub control circuit 101, and the like. The main RAM 95 is provided with a storage area for storing various data such as an internal winning combination determined by execution of the control program.

  The main CPU 93 is connected to a clock pulse generation circuit 96, a frequency divider 97, a random number generator 98, and a sampling circuit 99. The clock pulse generation circuit 96 and the frequency divider 97 generate clock pulses. The main CPU 93 executes a control program based on the generated clock pulse. The random number generator 98 generates a random number in a predetermined range (for example, 0 to 65535). The sampling circuit 99 extracts one value from the generated random numbers.

  The main CPU 93 counts the number of times pulses are output to the stepping motors of the reels 3L, 3C, 3R after detecting the reel index. Thereby, the main CPU 93 manages the rotation angle of each reel 3L, 3C, 3R (mainly, how many symbols the reel has rotated).

  The reel index is information indicating that the reel has made one revolution. This reel index is provided at a predetermined position of each of the reels 3L, 3C, 3R, for example, with a light emitting unit and a light receiving unit. Detection is performed by a reel position detection unit (not shown) including a detection piece interposed therebetween.

  Here, the management of the rotation angle of each reel 3L, 3C, 3R will be specifically described. The number of pulses output to the stepping motor is counted by a pulse counter provided in the main RAM 95. Each time the output of a predetermined number of pulses (for example, 16 times) necessary for the rotation of one symbol is counted by the pulse counter, the symbol counter provided in the main RAM 95 is incremented by one. The symbol counter is provided for each reel 3L, 3C, 3R. The value of the symbol counter is cleared when a reel index is detected by a reel position detector (not shown).

  In other words, in the present embodiment, by managing the symbol counter, it is possible to manage how many symbols have been rotated since the reel index was detected. Therefore, the position of each symbol on each reel 3L, 3C, 3R is detected with reference to the position where the reel index is detected.

  In the present embodiment, the maximum number of sliding symbols is basically set to 4 symbols. Therefore, when the left stop button 17L is pressed, the symbol of the left reel 3L in the middle of the display window 4 and each symbol within the range up to four symbols ahead can be stopped in the middle of the display window 4. It becomes a simple design.

<Sub control circuit>
Next, the sub control circuit 101 constituted by the sub control board 42 will be described with reference to FIG. FIG. 5 is a block diagram illustrating a configuration example of the sub control circuit 101 of the pachislot machine 1.

  As shown in FIG. 5, the sub control circuit 101 as the sub control unit is electrically connected to the main control circuit 91, and the content of the presentation is determined and executed based on the command signal transmitted from the main control circuit 91. And the like, and controls peripheral devices such as the liquid crystal display device 11, the LED group 25, and the speakers 23L and 23R. The sub control circuit 101 basically includes a sub CPU 102, a sub RAM 103, a rendering processor 104, a drawing RAM 105, and a driver 106.

  The sub CPU 102 controls the output of video, sound and light according to the control program stored in the ROM cartridge substrate 76 in accordance with the command signal transmitted from the main control circuit 91. The ROM cartridge substrate 76 basically includes a program storage area and a data storage area.

  A control program executed by the sub CPU 102 is stored in the program storage area. For example, the control program includes a main board communication task for controlling communication with the main control circuit 91 and an effect registration task for extracting and registering effect contents (effect data) by extracting effect random numbers. Is included. In addition, a drawing control task for controlling the display of an image by the liquid crystal display device 11 (see FIG. 2) based on the determined contents of presentation, a lamp control task for controlling the output of light by a light source such as the LED group 25, and speakers 23L and 23R. This includes a voice control task for controlling the output of sound.

  The data storage area includes a storage area for storing various data tables, a storage area for storing effect data constituting each effect content, and a storage area for storing animation data related to creation of video. Also included are a storage area for storing sound data related to BGM and sound effects, a storage area for storing lamp data related to the light on / off pattern, and the like.

  The sub-RAM 103 is provided with a storage area for registering the determined contents and effects data, and a storage area for storing various data such as an internal winning combination transmitted from the main control circuit 91.

  The sub CPU 102, the rendering processor 104, the drawing RAM (including the frame buffer) 105, and the driver 106 create a video according to the animation data designated by the content of the presentation, and display the created video on the liquid crystal display device 11.

  Further, the sub CPU 102 causes the speakers 23L and 23R to output sounds such as BGM according to the sound data designated by the contents of the production. Further, the sub CPU 102 controls lighting and extinguishing of the LED group 25 according to the lamp data designated by the contents of the effect.

<External concentration terminal board>
Next, various signals transmitted from the external concentrated terminal board 56 to the external device 200 will be described with reference to FIG. FIG. 6 is a schematic diagram illustrating an example of various signals transmitted from the external concentration terminal board 56 to the external device 200. Here, the external device 200 is configured by, for example, an external display that displays the number of games, the number of AT operations, and the like, a game room host computer, and the like.

  The main control board 41 is connected to the input terminal 56 a of the external concentration terminal board 56 through a plurality of electric cables and the cabinet side relay board 53. The external concentration terminal board 56 receives signals such as the number of inserted / withdrawn medals from the main control board 41, the number of games, information on the presence / absence of AT operation, etc. via the input terminal 56a, and outputs these signals to the output terminal 56b. To the external device 200. The external indicator is installed, for example, above the pachislot machine 1, and updates the display in conjunction with the progress of the number of games and the AT operation, or notifies the AT operation by a lamp or the like.

  Here, the medal insertion signal is a signal that makes it possible to recognize the medal insertion, and is output when the start lever 16 is operated. The medal payout signal (hereinafter also simply referred to as a payout signal) is a signal that makes it possible to recognize medal payout or replay, and is output at the time of medal payout (including credit storage) or replay operation.

  The external signal 1 is a signal that makes it possible to recognize that GG, which will be described later, has been started. For example, the push order of specific push order bells (for example, 213C bells 1 to 6 and 213L bells 1, 2, etc.) Stop order) Output after the third stop in the game when two correct answers occur in succession.

  The external signal 2 is a signal that makes it possible to recognize that a GG based on GOD matching, which will be described later, has been started, and is output after the third stop in the game when the combination related to GOD1 and GOD2 is displayed. Note that the output timing of the external signal 2 after the third stop varies depending on the value of a GOD counter described later. Details of the output timing of the external signal 2 will be described later.

  The external signal 3 is a signal that makes it possible to recognize that one of the red 7 lip 1 to red 7 lip 3 and the right red 7 lip 1, 2 has won the internal winning combination. For example, the red 7 lip 1 -Output after the third stop in the game when the internal winning combination of red 7 lip 3, right red 7 lip 1, 2 is won.

  In addition, for example, a security signal is a signal that enables recognition when an error occurs (for example, a medal jam), when a door is opened, when a setting is changed, and the like, and is output when each event occurs.

  Here, the main CPU 93 transmits the various signals described above as signals representing the state of the pachislot machine 1 to the external device 200 via the external concentration terminal board 56. In this way, the main CPU 93 constitutes a state transmission unit.

[Changes in gaming state]
The main CPU 93 shifts the two game states, the main game state and the RT game state, as the game state of the pachislot machine 1.

<Transition of main game state>
As shown in FIG. 7, the main CPU 93 takes one of a general gaming state and a BB gaming state as the main gaming state. In the general gaming state, the main gaming state shifts to the BB gaming state when a big bonus (hereinafter simply referred to as “BB”) act as a bonus game is won. Here, BB is in a state where it is always internally won from the time when the internal winning is won until the BB working combination is won, and this state is hereinafter referred to as “BB carryover state”.

  In the BB gaming state, the main gaming state is when the BB end condition is satisfied, specifically, when medals exceeding a prescribed number (86 in the present embodiment) are paid out in the BB gaming state. Shifts to the general gaming state. The operation and termination of BB are controlled by the main CPU 93. Thus, the main CPU 93 constitutes bonus game control means.

  The main CPU 93 takes either the BB general gaming state or the RB gaming state as the BB gaming state.

  When transitioning from the general gaming state to the BB gaming state, the main gaming state transitions to the BB general gaming state. In the BB general gaming state, the main gaming state shifts to the RB gaming state when the RB operating combination wins. Here, the RB is always in the state of internal winning from the time of internal winning until the winning combination of the RB is won, and this state is hereinafter referred to as “RB carryover state”.

  In the RB gaming state, the winning probability of each small role is defined to be low, but the display probability that the combination of symbols constituting any small role is displayed is set to be higher than the BB general gaming state. ing.

  In the RB gaming state, the main gaming state is when the RB end condition is satisfied, specifically, when the number of games in the RB gaming state becomes a specified number of times (in this embodiment, once), or When the number of winning prizes for a small combination with a payout reaches a specified number of times (in this embodiment, 1), the game proceeds to the BB general gaming state. The transition of the main game state in the BB game state is controlled by the main CPU 93. Thus, the main CPU 93 constitutes bonus game state transition control means.

  In the RB gaming state, the main gaming state shifts to the general gaming state when the BB end condition is satisfied. Further, in the RB carryover state, the main game state shifts to the general game state when the BB end condition is satisfied.

<Transition of RT gaming state>
In the general gaming state, the main CPU 93 takes either the RT0 gaming state or the RT1 gaming state as the RT gaming state. That is, the main CPU 93 shifts the RT gaming state between the RT0 gaming state and the RT1 gaming state. Thus, the main CPU 93 constitutes RT game state transition control means.

  The RT0 gaming state is a replay low-probability state (low RT gaming state) in which the winning probability of the replaying role that is the act of operating the replay is relatively lower than the RT1 gaming state. The RT1 gaming state is a replay high probability state (high RT gaming state) in which the winning probability of the replay role is relatively higher than the RT0 gaming state.

  In the RT0 gaming state in the general gaming state, the RT gaming state transitions to the RT1 gaming state when the BB operating combination is determined as the internal winning combination. On the other hand, in the RT1 gaming state in the general gaming state, the RT gaming state transitions to the RT0 gaming state when the BB operating combination wins and then the BB is finished.

  Here, the RT1 gaming state and the RT0 gaming state are not RTs managed by the number of games, but are shifted to other gaming states only when the above-described transition condition is satisfied. In that sense, the RT1 gaming state and the RT0 gaming state are infinite RTs.

  As the RT game state transition conditions, instead of the above-described transition conditions, a combination of specific symbols is displayed as a combination of symbols for transferring the winning combination of the BB, the end of the BB, and the RT gaming state. Or a predetermined number of unit games may be executed.

[Sub gaming state of gaming machine]
FIG. 8 is a state transition diagram of the sub gaming state in the pachislot machine 1. As described above, while the RT game state is shifted by the main CPU 93, the sub CPU 102 determines the content of the effect, thereby notifying the stop operation of the reels 3L, 3C, 3R, thereby playing an internal winning combination. It is advantageous for the player to win or not win, or shift the sub game state.

  As described above, the sub CPU 81 constitutes a game state transition means for transitioning the effect state to the advantageous game state in which the information of the advantageous stop operation related to the medal grant is notified when the specific condition is satisfied.

  In this embodiment, the advantageous gaming state corresponds to “AT”, which is a state in which the sub CPU 102 notifies the stop operation of the reels 3L, 3C, 3R so that the internal winning combination is advantageously won or not won for the player. To do.

  In the present embodiment, “AT” includes “GG”, “EG”, “PEG”, and “SEG” described later. A state in which the RT state is an AT state and the replay high probability state is referred to as “ART”.

<GG>
“GG” is performed with a predetermined number of games (in this embodiment, 100 games) as one set. In this way, in the GG, since the internal winning combination can be won so as to increase the number of winnings without inserting medals, the more medals are set, the more medals are acquired. be able to. For this reason, in the pachislot machine 1 of the present embodiment, adding the number of GG sets (hereinafter also referred to as “addition”) greatly affects medal acquisition.

  When the specific condition is established, the sub CPU 102 shifts the sub gaming state to GG. Specific conditions include winning a lottery according to the internal winning combination and winning a lottery according to the history of the internal winning combination as a result of the unit game. Thus, the sub CPU 102 constitutes a game state transition unit.

  The lottery corresponding to the history of the internal winning combination is won when a specific internal winning combination is won continuously for a predetermined number of times or when a specific internal winning combination is determined for a predetermined number of times within a predetermined number of games. Done if you do.

  In addition, when the sub CPU 102 shifts the sub gaming state to GG, the sub CPU 102 notifies the GG that the sub gaming state has been determined to shift to a combination of a plurality of decorative symbols displayed on the liquid crystal display device 11. Thus, the sub CPU 102 and the liquid crystal display device 11 constitute a gaming state transition notification unit.

<CZ>
When the special condition is satisfied, the sub CPU 102 shifts the sub game state to a special mode (hereinafter referred to as “CZ”) in which the sub game state can be shifted to GG even when the specific condition is not satisfied. Special conditions include winning a lottery according to the internal winning combination history. In this way, the sub CPU 102 constitutes a special mode transition unit.

  When the sub gaming state is CZ, the sub CPU 102 determines a plurality of decorative symbols to be displayed on the liquid crystal display device 11, in the present embodiment, three decorative symbols by lottery. Specifically, when the sub gaming state is CZ, the sub CPU 102 determines at least one decorative symbol to be displayed on the liquid crystal display device 11 by lottery every time a stop operation is detected by the stop switch 17S. In this way, the sub CPU 102 constitutes a decorative symbol determination unit.

  Each time the sub CPU 102 determines a decorative design, the sub CPU 102 displays the determined decorative design on the image display means. In this way, the sub CPU 102 constitutes a decorative symbol display unit. When the sub game state is CZ, the sub CPU 102 shifts the sub game state to GG when a special transition condition is established in which the types of three decorative symbols displayed on the liquid crystal display device 11 are the same.

  Specifically, the sub CPU 102 shifts the sub game state to any one of CZ1 to CZ4 in accordance with the sub game state at the time of shifting to CZ. When the sub CPU 102 is in the CZ (CZ1 or CZ2) in which the sub gaming state has shifted from the normal state, the special transition condition in which the types of the three decorative symbols displayed on the liquid crystal display device 11 are the same is satisfied. The sub gaming state is shifted to GG.

  On the other hand, when the sub game state is CZ (CZ3 or CZ4) in which the sub game state is shifted from GG, the special transition condition in which the types of the three decorative symbols displayed on the liquid crystal display device 11 are the same is satisfied. Is added with GG.

  Further, when the sub game state is CZ, the sub CPU 102 has predetermined decoration symbols displayed on the liquid crystal display device 11 even if the types of the three decoration symbols displayed on the liquid crystal display device 11 are not the same. Each time a specific combination of decorative symbols (hereinafter referred to as “GG winning reach”) is constructed, GG is added, and the sub gaming state is maintained in CZ until the end condition of CZ is satisfied.

  In the present embodiment, CZ end conditions include that a special transition condition is satisfied and that CZ has continued for 5 games. Note that the GG winning reach is not displayed on the liquid crystal display device 11 when the sub gaming state is normal, and the liquid crystal display device is displayed during the GG indication before the sub gaming state shifts to GG after winning the GG. 11 is included in the reach eye which is the display outcome displayed in FIG.

  Further, the sub CPU 102 performs the next processing in the CZ on the condition that when the sub gaming state is CZ, the combination of the decorative symbols displayed on the liquid crystal display device 11 partially includes the same type of decorative symbols. In the unit game, hold (HOLD) for maintaining the combination of the same type of decorative symbols is performed, and decorative symbols that are not maintained are determined by lottery.

  In the present embodiment, the sub CPU 102 will be described on the assumption that, in the next unit game in the CZ, decorative symbols that are not maintained are determined by lottery on the condition that the hold is performed. In the unit game, every time a stop operation is detected by the stop switch 17S, a decorative symbol that is not maintained may be determined by lottery.

  In the present embodiment, the sub CPU 102 does not necessarily hold the liquid crystal display on the condition that the combination of the decorative symbols displayed on the liquid crystal display device 11 includes a part of the same type of decorative symbols. The holding is performed on condition that the combination of the decorative symbols displayed on the device 11 is a special combination among the combinations that partially include the same type of decorative symbols.

  For example, when the combination of decorative symbols displayed on the liquid crystal display device 11 is “7S7”, as shown in FIG. 111, the hold is performed, but the combination of decorative symbols displayed on the liquid crystal display device 11 is “ In the case of “7V7”, no hold is performed.

<EG>
When the specific transition condition is satisfied, the sub CPU 102 shifts the sub game state to an additional game state (hereinafter referred to as “EG”) in which a lottery for adding GG is performed over 16 games as the prescribed unit game number.

  For example, when the sub game state is CZ and the sub game state is CZ, for example, “SSS” is displayed as a special symbol combination on the liquid crystal display device 11, the sub CPU 102 shifts the sub game state to GG and shifts to EG. Make

  When the sub game state is EG, for example, the sub CPU 102 wins an internal winning combination in which red 7 is aligned on the display window 4, and the red 7 alignment is displayed on the display window 4 as a predetermined symbol combination. On this condition, GG is added and rewinding is performed to set the remaining number of EG games to 16 which is the specified unit game number. In this way, the sub CPU 102 constitutes an additional game number setting means.

  When the sub CPU 102 is in the EG state and the GG is added, the sub CPU 102 advantageously adds GG to the player according to the number of remaining EG games. In this way, the sub CPU 102 constitutes an advantageous gaming state addition means.

  Specifically, when the sub game state is EG, the sub CPU 102 adds GG having a higher continuation rate as the number of remaining EG games is smaller. Here, the GG continuation rate refers to a probability that GG is further added when GG is added. That is, the sub CPU 102 performs lottery until it becomes non-winning at the GG continuation rate, and adds GG for the number of wins.

<PEG>
When the special transition condition is satisfied when the sub gaming state is EG, the sub CPU 102 has an added high probability state (hereinafter referred to as “PEG”) in which the probability that the GG is added is relatively higher than the EG. The sub gaming state is transferred to. Special transition conditions include winning a PEG promotion lottery performed when the sub gaming state shifts to EG, and winning a rewind to PEG by a rewind lottery.

  When the sub game state is PEG, the sub CPU 102 adds GG on the condition that it wins the rewind, sets the remaining number of games of the EG to 16, and sets the sub game state to the rewind lottery. Transfer to EG or PEG.

  Note that the sub CPU 102 has a case where the internal winning combination history in the PEG satisfies a predetermined condition, rather than the case where the internal winning combination history satisfies a predetermined condition in a gaming state other than PEG. However, GG may be advantageously added to the player.

  In other words, the lottery according to the history of the internal winning combination is more advantageous to the player when the sub game state is PEG than when the sub game state is other than PEG. It may be.

  Specifically, the lottery according to the history of the internal winning combination is such that the winning probability of GG and CZ is higher when the sub gaming state is PEG than when the sub gaming state is other than PEG. May be.

  Further, the sub CPU 102 gives the player the case where the small winning combination is determined as the internal winning combination in the PEG rather than the case where the small winning combination is determined as the internal winning combination in the gaming state other than PEG. On the other hand, GG may be advantageously added.

  Specifically, the lottery corresponding to the internal winning combination may be such that the winning probability of GG and CZ is higher when the sub gaming state is PEG than when the sub gaming state is other than PEG. Good.

<SEG>
When the sub game state is EG and the special condition is satisfied, the sub CPU 102 stops subtracting the number of EG games over the number of unit games determined by lottery until the GG is added (hereinafter referred to as GG). , Referred to as “SEG”).

  That is, when the sub gaming state is SEG, the number of EG games is substantially increased, and the probability that GG is added is substantially increased. As a special condition, there is a case where a SEG addition game number lottery described later is won.

[Data table stored in main ROM]
9 to 23 show various data tables stored in the main ROM 94.

<Pattern arrangement table>
The symbol arrangement table shown in FIG. 9 represents the arrangement of symbols arranged on the surface of each of the left reel 3L, the middle reel 3C, and the right reel 3R. The symbol arrangement table defines the correspondence between the twenty symbol positions “0” to “19” and symbols corresponding to these symbol positions.

  Symbol positions “0” to “19” indicate the positions of symbols arranged along the rotation direction in each of the left reel 3L, the middle reel 3C, and the right reel 3R. The symbols corresponding to the symbol positions “0” to “19” can be specified by referring to the symbol arrangement table using the value of the symbol counter.

  The types of symbols are "GOD1," "GOD2," "Red 7," "Upper half circle," "Lower half circle," "Yellow 7," "Blue 7A," "Blue 7B," "Blue 7C" And “Blue 7D”.

  Here, “GOD1” and “GOD2” need only be identifiable as having different symbols internally by the main CPU 93. In the present embodiment, “GOD1” and “GOD2” are symbols that can be recognized by the player like the same symbol. To do. Similarly, “blue 7A”, “blue 7B”, “blue 7C”, and “blue 7D” need only be identifiable by the main CPU 93 as internally different symbols, and in the present embodiment, they are the same. And the symbol that can be recognized by the player.

<Design code table>
As shown in FIG. 10, each symbol arranged on each reel 3L, 3C, 3R is specified by a symbol code table, and is distinguished by 1 byte (8 bits) data in this embodiment. The symbol code table shown in FIG. 10 represents symbol codes as data for specifying symbols arranged on the surfaces of the three reels 3L, 3C, 3R.

  For example, the symbol arrangement table shown in FIG. 9 has been described as representing the arrangement of symbols arranged on the surface of each of the left reel 3L, the middle reel 3C, and the right reel 3R, but is actually stored in the main ROM 94. The symbol arrangement table shows the arrangement of symbol codes for identifying symbols arranged on the surfaces of the left reel 3L, the middle reel 3C and the right reel 3R.

  In the present embodiment, the symbols used in the pachislot machine 1 are “GOD1,” “GOD2,” “Red 7,” “Upper half circle,” “Lower half circle,” “Yellow 7,” and “Blue” as described above. There are 10 types of “7A”, “Blue 7B”, “Blue 7C” and “Blue 7D”.

  In the symbol code table, “1” is assigned as the symbol code for the “GOD1” symbol. Also, “2” is assigned as the symbol code for the “GOD2” symbol. Also, “3” is assigned as the symbol code for the “red 7” symbol.

  Similarly, from “4” as the symbol code for each symbol of “upper half circle”, “lower half circle”, “yellow 7”, “blue 7A”, “blue 7B”, “blue 7C” and “blue 7D” “10” is assigned.

<Design combination table>
The symbol combination table shown in FIGS. 11 to 13 is a combination of symbols identified by the storage area identification data represented by 22 bytes (hereinafter referred to as “combination”) and a combination displayed on the effective line. The number of medals paid out is associated. In addition, in the symbol combination table shown in FIGS. 11 to 13, a name and a simple description (remarks) are given to each combination in order to facilitate understanding of the invention.

  For example, when a combination of “lower half circle-upper half circle-blue 7A” called “BB” is displayed along the active line, medals are not paid out, but BB operates. That is, when “BB” is displayed along the active line, the main gaming state shifts to the BB operating state.

  In addition, when a combination of “GOD1-yellow 7-red 7” called “T Lip 1” is displayed along the active line, the re-game is activated. The same applies to “T Lip 2”.

  When a combination of “GOD1-blue 7A-GOD1” called “CD lip 1” is displayed along the active line, the re-game is activated. The same applies to “CD Lip 2” to “CD Lip 4”.

  In addition, when a combination of “GOD1-blue 7A-lower semicircle” called “B yellow lip 1” is displayed along the active line, the replay is activated. The same applies to “B Yellow Lip 2” to “B Yellow Lip 4”.

  In addition, when a combination of “blue 7A-blue 7A-blue 7A” called “C Lip 1” is displayed along the active line, the replay is activated. The same applies to “C Lip 2” to “C Lip 32”.

  Further, when a combination of “red 7-red 7-red 7” called “red 7 lip 1” is displayed along the active line, the re-game is activated. The same applies to “Red 7 Lip 2” to “Red 7 Lip 44”.

  When a combination of “blue 7B-lower semicircle-red 7” called “red 7F lip 1” is displayed along the active line, the re-game is activated. The same applies to “Red 7F Lip 2” to “Red 7 Lip 43”.

  In addition, when a combination of “upper semicircle-yellow 7-yellow 7” called “unquestioned red F lip 1” is displayed along the active line, the replay is activated. The same applies to “unquestioned red F lip 2” to “unquestioned red F lip 5”.

  Further, when a combination of “upper semicircle-GOD1-GOD1” called “T bell 1” is displayed along the active line, 15 medals are paid out. The same applies to “T bell 2”, “CD bell” and “C bell”.

  When a combination of “yellow 7-yellow 7-lower semicircle” called “2nd bell” is displayed along the active line, three medals are paid out. The same applies to “3rd bell”.

  Further, when a combination of “GOD1-blue 7A-blue 7A” called “bell 1” is displayed along the active line, one medal is paid out. The same applies to “Bell 2” to “Bell 32”.

  When a combination of “GOD1-yellow 7-GOD1” called “CU bell” is displayed along the active line, 15 medals are paid out. Further, in the case of a so-called GOD alignment in which a combination of “GOD1-GOD1-GOD1” called “GOD1” is displayed along the active line, 15 medals are paid out. The same applies to “GOD2”.

  When a combination of “red 7-red 7-GOD 1” called “special SP1” is displayed along the active line, one medal is paid out. The same applies to “special SP2” to “special SP8”.

<Combination table by flag>
The flag-specific combination tables shown in FIGS. 14 to 16 indicate combinations that are permitted to be displayed on the active line in correspondence with the internal winning combination. As the internal winning combination in the present embodiment, “normal lip”, “right red 7F lip”, “right red 7 lip 1”, “right red 7 lip 2”, “B yellow lip”, “C lip”, “Red 7F Lip 1”, “Red 7F Lip 2”, “Red 7F Lip 3”, “Red 7 Lip 1”, “Red 7 Lip 2”, “Red 7 Lip 3”, “213C Bell 1”, “213C” "Bell 2", "213C Bell 3", "213C Bell 4", "213C Bell 5", "213C Bell 6", "231CD Bell 1", "231CD Bell 2", "231CD Bell 3", "231CD Bell 4" ”,“ 231CD Bell 5 ”,“ 231CD Bell 6 ”,“ 312C Bell ”,“ 312T Bell 1 ”,“ 312T Bell 2 ”,“ 312T Bell 3 ”,“ 312T Bell 4 ”,“ 312CD Bell ”,“ 321C ” "Bell", "321T Bell 1", "321T Bell 2", " “21T Bell 3”, “321T Bell 4”, “321CD Bell”, “213L Bell 1”, “213L Bell 2”, “231L Bell 1”, “231L Bell 2”, “312L Bell 1”, “312L Bell 2” ”,“ 321L Bell 1 ”,“ 321L Bell 2 ”,“ Left CU Bell ”,“ CU Bell ”,“ C Bell ”,“ Special Role ”,“ Special Foot ”,“ Special SP ”,“ GOD ”, There are “RB role 1”, “RB role 2”, “RB role 3” and “BB”.

  For example, when the internal winning combination is “BB”, the main CPU 93 permits the combination of “BB” to be displayed on the active line. That is, when the internal winning combination is “BB”, it indicates that BB is won internally.

  Similarly, when the internal winning combination is “Red 7 Lip 1”, the main CPU 93 enables the combination of “T Lip 1”, “T Lip 2” and “Red Lip 1” to “Red Lip 44”. Allow to be displayed on the line.

  When the internal winning combination is “GOD”, the main CPU 93 allows the combination of “GOD1”, “GOD2”, and “Bell 1” to “Bell 16” to be displayed on the active line.

<Internal lottery table>
A plurality of internal lottery tables shown in FIGS. 17 to 19 are stored in the main ROM 94 corresponding to each gaming state and each inserted number, and indicate the winning probability of each flag with 65536 as the denominator for each setting 1-6. Yes. In particular, in the present embodiment, an internal lottery table when the number of inserted sheets is “3” will be described.

  Here, FIG. 17 shows an internal lottery table when three cards are played in the RT0 gaming state when the main gaming state is in the general gaming state other than the BB gaming state. For example, in any of the settings 1 to 6 in FIG. 17, the probability of “out” is “0/65536”, the probability that “BB” wins internally is “3969/65536”, and “normal” The probability that “Lip” wins internally is “3640/65536”, and the probability that “Special Role” wins internally is “640/65536”.

  FIG. 18 shows an internal lottery table when three cards are stacked in the RT1 gaming state, that is, the BB carryover state when the main gaming state is a general gaming state that is not the BB gaming state. For example, in FIG. 18, in any case of setting 1 to setting 6, the probability of “out of” is “0/65536”, and the probability that “BB + GOD” is internally won is “8/65536”.

  FIG. 19 shows an internal lottery table when the main gaming state is in the BB gaming state, that is, when three cards are stacked in the BB gaming state. For example, in FIG. 19, in any of the settings 1 to 6, the probability of “out of” is “12948/65536”, and the probability that “RB combination 1” wins internally is “5054/65536”.

<Cylinder stop initial setting table>
The spinning cylinder stop initial setting table shown in FIG. 20 is information for stopping the reels 3L, 3C, 3R, and is predetermined according to the internal winning combination. The main CPU 93 refers to the rotation stop initial setting table, acquires the rotation stop number corresponding to the internal winning combination, and acquires various data for stopping the reels 3L, 3C, 3R. Yes.

  Specifically, in the rotation stop initial setting table, in addition to the determination data for each pressing order in association with the rotation stop number, the table number selection data and the change data table number after the first rotation first stop The first cylinder stop data table number and the initial data after the first cylinder first stop are defined according to the gaming state. These various data indicate various table numbers to be selected in the stop control of the reels 3L, 3C, 3R according to the progress of the unit game.

  The “determination data by pressing order” includes a pull-in priority table number and a pull-in priority selection table number. The “pull-in priority table number” is a number for selecting the pull-in priority table shown in FIG. Further, the “drawing priority order selection table number” is a number for selecting the drawing priority order selection table shown in FIG.

  The “table number selection data” is a value that is referred to when all reels are stopped when the first stop reel is other than the left reel 3L, and includes a stop table number and a change status.

  The “stop table number” is a number for selecting a stop table (not shown) to be referred to when all reels are stopped when the first stop reel is other than the left reel 3L.

  The “change status” of the table number selection data is data for changing the line status for each game representing the line referred to in the stop table selected based on the stop table number.

  The change data table number after the first cylinder first stop, the first cylinder stop data table number, and the initial data after the first cylinder first stop indicate that the first cylinder is the first cylinder, that is, the left reel 3L. This data is referenced when

  The “first cylinder stop data table number” is a number for selecting a first cylinder stop data table to be referred to when stopping the first cylinder from a first cylinder stop data table (not shown).

  The “initial data after first stop of the first cylinder” is data that is referred to when the second and third cylinders are stopped, and includes a table number and a line status. The “table number” is a number for selecting a stop data table (not shown) after the first cylinder reference that is referred to when stopping the second and third stop reels.

  The “change status” of the initial data after the first stop first stop indicates the line status for each game representing the line referred to in the stop data table after the first stop first stop selected based on the table number. This is data to change.

  “Change data table number after first cylinder first stop” is used to select a change data table (not shown) after first cylinder first stop for changing initial data after first cylinder first stop. It is data of.

<Pull-in priority table>
The drawing priority table shown in FIG. 21 represents which combination is drawn with priority among a plurality of combinations that can be displayed in the drawing range corresponding to the internal winning combination. In FIG. 21, data of a winning operation flag representing a combination combination is omitted.

  In the drawing priority order table, the drawing priority order of the combination indicated by the winning action flag is shown. The “pull-in priority data” is information provided for the main CPU 93 to identify the pull-in priority.

  For example, in the drawing priority table number “00”, “T Lip 1, 2”, “CD Lip 1-4”, “C Lip 1-32”, “Red 7 Lip 1-44” and “Red 7F Lip” If it is determined that there is a possibility of winning, since “T Lip 1” has a higher priority than “BB”, the reel 3L that is rotating so that “T Lip 1” is drawn with priority. , 3C, 3R stop control is performed.

<Pull-in priority selection table>
In the pull-in priority selection table shown in FIG. 22, a pull-in priority table number for a stop operation type indicating the order of reel stop operations is associated with each pull-in priority selection table.

  For example, in the pull-in priority order selection table number “01”, when the first stop operation is “left”, the pull-in priority table number “03” is associated and the first stop operation is “right”. In this case, the pull-in priority table number “00” is associated.

  In the drawing priority order selection table number “01”, when the first stop operation is “left” and the second stop operation is “middle” during the second stop operation (“left → middle” in the figure), When the pull-in priority table number “03” is associated, the first stop operation is “right” and the second stop operation is “left” during the second stop operation (“right → left” in the figure), The pull-in priority table number “00” is associated.

<Priority order table>
The priority order table shown in FIG. 23 is referred to determine the number of sliding pieces for each of the reels 3L, 3C, 3R. In the present embodiment, one priority order table is used. In the priority order table, the number of sliding frames is associated with the sliding frame number determination data in accordance with the priority order.

  For example, in the priority order table, when the sliding piece number determination data is “3”, the number of sliding pieces “3” has the highest priority order, and then the number of sliding pieces “1”, “0”, “4” ”,“ 2 ”in order of priority.

  In this case, if the combination corresponding to the internal winning combination can be displayed on the effective line when the corresponding reel is slid by 3 frames, the number of sliding pieces “3” is selected and the internal winning combination is supported. If the combination cannot be displayed on the active line, the priority order is lowered until the combination can be displayed on the active line.

  If the combination corresponding to the internal winning combination cannot be displayed on the active line even if the priority order is lowered to the number of sliding pieces “2”, or if it is “out of” with no internal winning combination, the highest priority is given. The number of sliding pieces “3” having the highest order is selected.

[Configuration of storage area allocated to main RAM]
24 to 31 show various storage areas allocated to the main RAM 95.

<Internal winning combination storage area>
The internal winning combination storing area shown in FIG. 24 is composed of seven storage areas of internal winning combination storing areas 0-6. In the internal winning combination storing areas 0 to 6, data (bits) corresponding to the internal winning combination associated with the combination is set to 1 in the combination table by flag shown in FIGS. 14 to 16, and other data is stored. Reset to zero.

<Display combination storage area>
The display combination storing area shown in FIG. 25 represents a combination that can be displayed along the active line after each reel of the reels 3L, 3C, 3R is stopped. That is, the display combination storing area represents a combination corresponding to the winning internal winning combination after all of the reels 3L, 3C, 3R are stopped. The display combination storing area is used for the main CPU 93 to identify the combination displayed along the active line after all the reels 3L, 3C, 3R are stopped.

<Design code storage area>
The number of symbol code storage areas shown in FIG. 26 is allocated as many as the number of valid lines. In each symbol code storage area, data that can be displayed along each valid line is set to 1, and the reels 3L, 3C, 3R Depending on the stop position, the data corresponding to the combination that cannot be displayed along the active line is reset to zero.

<Carry-over portion storage area>
The carryover combination storage area shown in FIG. 27 stores data relating to the carryover combination. For example, on condition that the main game state becomes the carryover state of BB (between BB flags), bit 7 of the carryover combination storage area is set to “1”, and on condition that BB is activated, the corresponding bit is set. Reset to “0”.

<Game state flag storage area>
The game state flag storage area shown in FIG. 28 stores data related to the main game state and the RT game state. For example, on condition that the main gaming state becomes the BB gaming state, bit 7 of the gaming state flag storage area is set to “1”, and bits 0 to 6 are reset to “0”.

  Also, on condition that the main gaming state becomes the RB gaming state, bit 6 of the gaming state flag storage area is set to “1”, and bits 0 to 5 and 7 are reset to “0”.

  On the condition that the RT gaming state becomes the RT0 gaming state, bit 5 of the gaming state flag storage area is set to “1”, and bits 0 to 4 and 6 to 7 are reset to “0”. Also, on condition that the RT gaming state becomes the RT1 gaming state, bit 4 of the gaming state flag storage area is set to “1”, and bits 0 to 3 and 5 to 7 are reset to “0”.

<Operation stop button storage area>
The operation stop button storage area shown in FIG. 29 stores the states of the stop buttons 17L, 17C, and 17R. Bit 7 corresponds to the stop button 17L, and “1” is stored in bit 7 when the stop button 17L is operated.

  Similarly, bit 6 corresponds to the stop button 17C, and “1” is stored in bit 6 when the stop button 17C is operated. Bit 5 corresponds to the stop button 17R, and “1” is stored in bit 5 when the stop button 17R is operated.

  Bit 3 corresponds to the stop button 17L, and “1” is stored in bit 3 when the stop button 17L is valid. Bit 2 corresponds to the stop button 17C, and “1” is stored in bit 2 when the stop button 17C is valid. Bit 1 corresponds to the stop button 17R, and “1” is stored in bit 1 when the stop button 17R is valid.

  In the present embodiment, effective stop buttons refer to the stop buttons 17L, 17C, and 17R that correspond to the reels 3L, 3C, and 3R that are rotating and that can be detected by the main CPU 93.

<Pressing order storage area>
The pressing order storage area shown in FIG. 30 is an area for storing information indicating the pressing order of the three stop buttons 17L, 17C, and 17R. Bit 7 corresponds to the pressing order “left → middle → right”. When the pressing order is “left → middle → right”, “1” is stored in bit 7 and the other bits are set to “0”. Reset.

  Similarly, bit 6 corresponds to the pressing order “left → right → middle”, bit 5 corresponds to the pressing order “middle → left → right”, and bit 4 has the pressing order “middle → right → left”. Bit 3 corresponds to the pressing order “right → left → middle”, and bit 2 corresponds to the pressing order “right → middle → left”.

<Retrieve priority data storage area>
The pull-in priority data storage area shown in FIG. 31 includes a left reel pull-in priority data storage area, a middle reel pull-in priority data storage area, and a right reel pull-in priority data storage area. The contents of the middle reel pull-in priority data storage area and the right reel pull-in priority data storage area are the same as those of the left reel pull-in priority data storage area. The data storage area will be described.

  The left reel pull-in priority data storage area stores pull-in priority data for each of the symbol position data. For example, among the drawing priority data in the drawing priority table shown in FIG. 21, any drawing priority data based on the state of the internal winning combination and the other reels 3C and 3R is stored for each symbol position.

[Data table referenced by sub CPU]
<Sub flag conversion table>
The subflag conversion table shown in FIG. 32 represents a subflag conversion number associated with the main flag corresponding number corresponding to the internal winning combination. Note that the subflag conversion table shown in FIG. 32 shows the appearance combination by pressing order in addition to the subflag conversion combination name corresponding to the subflag conversion number for easy understanding of the invention.

  Here, the appearance combination according to the pressing order represents the number of medals to be paid out or the pattern displayed in the frame of the display windows 4L, 4C, 4R with respect to the pressing order. In the sub-flag conversion table shown in FIG. 32, the pressing order is represented by numbers, the stop button 17L is represented by “1”, the stop button 17C is represented by “2”, and the stop button 17R is represented by “3”.

  For example, the column in which the pressing order is represented as “213” indicates the number of medals to be paid out when being operated in the order of the stop buttons 17C, 17L, and 17R or the symbols displayed in the frames of the display windows 4L, 4C, and 4R. Is displayed.

  “0” to “25” are assigned as the subflag conversion numbers, and “out of”, “213 bell”, “231 bell”, “312 bell”, “321 bell”, “213L bell”, “ "231L Bell", "312L Bell", "321L Bell", "Normal Lip", "Right Red 7F Lip", "Right Red 7 Lip 1", "Right Red 7 Lip 2", "B Yellow Lip", "C “Lip”, “Left CU Bell”, “CU Bell”, “C Bell”, “Special Role”, “Special Foot”, “Special SP”, “Red 7F1”, “Red 7F2”, “Red 7N”, “Red 7SP” and “GOD” are respectively indicated.

  For example, the subflag conversion number 1 is associated with the main flag corresponding numbers 13 to 18 (that is, “213C bell 1” to “213C bell 6”), and the subflag conversion combination name is “213 bell”.

  The payout number of “213 bells” is 1 with a probability of 1/8 when the stop buttons 17C, 17L, and 17R are operated at random timing when the pushing order is “123” or “132”. And becomes 0 with a probability of 7/8. The payout number of “213 bell” is 15 when the push order is “213”, and is 1 when the push order is “231”, “312”, or “321”.

  The subflag conversion number 9 is associated with the main flag correspondence number 1 (that is, “normal lip”), and the subflag conversion combination name is “normal lip”. The display mode of “normal lip” is “upper blue 7” regardless of the pressing order, and “blue 7-blue 7-blue 7” is displayed in the upper part of the frame of the display windows 4L, 4C, 4R.

<Conversion table by subflag state>
The sub-flag state conversion tables shown in FIG. 33 to FIG. 39 normally include seven tables corresponding to CZ1 and CZ2, GG, CZ3 and CZ4, EG, SEG and PEG sub-gaming states.

  In each subflag state conversion table, the probability that the subflag conversion number before conversion shown in the row direction (indicated by the subflag conversion role name in the figure) is converted into the converted subflag conversion number shown in the column direction Is represented.

  The sub-flag conversion combination names after conversion are different from the sub-flag conversion combination names before conversion, and “subject”, “bell spill”, “213 bell”, “231 bell” for the sub-flag conversion numbers “0” to “25”. ”,“ 312 Bell ”,“ 321 Bell ”,“ 213L Bell ”,“ 231L Bell ”,“ 312L Bell ”,“ 321L Bell ”,“ Normal Lip ”,“ Left Normal Lip ”,“ Medium Normal Lip ”,“ “B Yellow Lip”, “C Lip”, “Left CU Bell”, “CU Bell”, “C Bell”, “Special Role SP”, “Right Red 7F”, “Red 7F1”, “Red 7F2”, “Red 7N "," Red 7SP ", and" GOD "are associated with each other.

  For example, when the sub gaming state is normal, “213 bell”, “231 bell”, “312 bell”, “321 bell”, “213L bell”, “231L bell”, “312L bell” and “321L” “Bell” is converted to “Bell spill” with a probability of 32768/32768.

  When the sub gaming state is GG, “normal lip” is converted to “normal lip” with a probability of 31744/32768, and is converted to “left normal lip” with a probability of 1024/32768.

<Sub flag lottery conversion table>
The sub-flag lottery conversion table shown in FIG. 40 represents the sub-flag lottery number for lottery associated with the sub-flag conversion number. In the sub-flag lottery conversion table shown in FIG. 40, the sub-flag lottery name corresponding to the sub-flag lottery number is shown for easy understanding of the invention.

  Similarly to the sub-flag state conversion table, in other tables described below, the sub-flag lottery name is used instead of the sub-flag lottery number for illustration and explanation as needed.

  For example, in the sub-flag lottery conversion table shown in FIG. 40, the sub-flag conversion combination “out” and “bell spill” are associated with the sub-flag lottery combination “out”. Similarly, “213 bell”, “231 bell”, “312 bell”, “321 bell” are associated with “15 bells”, and “213L bell”, “231L bell”, “312L bell”, “ “321L Bell” is associated with “Three Bells”.

<CZ number group lottery table>
The CZ number group lottery table shown in FIG. 41 includes seven tables corresponding to the sub game states CZ1 to CZ4. Each CZ number group lottery table represents the probability that each of the number groups A to H is determined for each sub-flag lottery combination.

  For example, when the sub gaming state is CZ1 and the sub flag lottery role is “C lip”, the number group C is determined with a probability of 21504/32768, and the number group D is determined with a probability of 3072/32768. , 7168/32768, and the number group H is determined with a probability of 1024/32768.

<CZ group group lottery table>
The CZ outcome group lottery table shown in FIG. 42 represents, for each number group, the probability that the type of decorative symbol displayed on the liquid crystal display device 11 is determined when the sub gaming state is any one of CZ1 to CZ4. ing. The sub CPU 102 determines a decorative symbol candidate from the decorative symbols displayed on the liquid crystal display device 11 by referring to the CZ outcome group lottery table according to the number group.

  The CZ outcome group lottery table includes four tables for first stop, second stop (without mirror), second stop (with mirror), and third stop. The CZ outcome group lottery table for the first stop is referred to when the left decorative symbol type is determined among the decorative symbols displayed on the liquid crystal display device 11 when the first stop reel is stopped.

  The CZ outcome group lottery table for the second stop (no mirror) is the second when the “mirror” is not determined as the type of the decorative symbol displayed on the liquid crystal display device 11 when the first stop reel is stopped. This is referred to when the type of the decorative pattern in the stop reel is determined.

  The CZ output group lottery table for the second stop (with a mirror) is the second stop when “mirror” is determined as the decorative symbol type displayed on the liquid crystal display device 11 when the first stop reel is stopped. This is referred to when the type of decorative symbol in the middle is determined when the reel is stopped. The CZ outcome group lottery table for the third stop is referred to when the right decorative symbol type is determined among the decorative symbols displayed on the liquid crystal display device 11 when the third stop reel is stopped.

  Each CZ outcome group lottery table represents the probability corresponding to the number group and the type of decorative design. Specifically, each CZ outcome group lottery table shown in FIG. 42 represents the probability that the type of each decorative symbol is determined in each number group.

  For example, in the first stop CZ outcome group lottery table, when the number group D is determined, “V” is determined as a decoration symbol type with a probability of 6553/32768, and 6556/32768. “S” is determined by the probability, and “mirror” is determined by the probability of 1966/32768.

  Similarly, when the number group G is determined in the second stop (no mirror) CZ outcome group lottery table, “3” is determined as the decorative symbol type with a probability of 10923/32768. , 10922/32768 with a probability of “7”, and 10923/32768 with a probability of “S”.

<CZ output group conversion table>
43 and 44, the CZ outcome group conversion table indicates the types of left, middle and right decorative symbols displayed on the liquid crystal display device 11 when the sub gaming state is any one of CZ1 to CZ4. An output group number corresponding to the display event is shown. In the CZ output group conversion table shown in FIGS. 43 and 44, in order to make the invention easier to understand, the types of decorative symbols constituting the display output and the contents of the output group are shown.

  For example, in the CZ output group conversion table, the display output “113” (display output number 1) is associated with the non-winning (output group number 0). That is, when the display output is “113”, the player is not won.

  In the CZ output group conversion table, the display output “177” (display output number 21) is associated with the HOLD winning A7 (output group number 1). That is, when the display outcome is “177”, a lottery of hold is performed.

  In the CZ output group conversion table, the display output “1VV” (display output number 28) is associated with the HOLD winning AV (output group number 2). That is, when the display output is “1 VV”, a lottery of hold is performed.

  In the CZ output group conversion table, the display output “1SS” (display output number 35) is associated with the HOLD winning AS (output group number 3). That is, when the display outcome is “1SS”, a lottery of hold is performed.

  In the CZ output group conversion table, the display output “7S7” (display output number 141) is associated with the HOLD winning B7 (output group number 4). That is, when the display outcome is “7S7”, a lottery of hold is performed.

  In the CZ output group conversion table, the display output “VSV” (display output number 178) is associated with the HOLD winning BV (output group number 5). That is, when the display item is “VSV”, a lottery of hold is performed.

  In the CZ output group conversion table, the display output “SVS” (display output number 209) is associated with the HOLD winning BS (output group number 6). That is, when the display item is “SVS”, a lottery of holding is performed.

  In the CZ output group conversion table, the display output “135” (display output number 8) is associated with the GG winning reach (output group number 7). That is, when the display result is “135”, GG is won.

  In the CZ output group conversion table, the display output “111” (display output number 0) is associated with the GG winning 135 (output group number 8). That is, if the display item is “111”, GG is won.

  In the CZ output group conversion table, the display output “777” (display output number 129) is associated with the GG winning 7 (output group number 9). That is, if the display result is “777”, GG is won.

  In the CZ output group conversion table, the display output “VVV” (display output number 172) is associated with GG winning 7 (output group number 10). That is, if the display item is “VVV”, GG is won.

  In the CZ output group conversion table, the display output “SSS” (display output number 215) is associated with the GG & EG winning S (output group number 11). That is, when the display item is “SSS”, GG and EG are won.

  In the CZ output group conversion table, the display output “V1V” (display output number 148) is associated with the heaven transition (output group number 12). That is, when the display outcome is “V1V”, the remaining CZ games are advantageous.

  For example, when the transition to heaven is displayed on the liquid crystal display device 11 and the remaining CZ game is in an advantageous state, the relative symbol candidate displayed on the liquid crystal display device 11 is relatively determined regardless of the sub flag lottery role. A small number of decorative designs are selected.

  Specifically, when the remaining CZ games are in an advantageous state, in the CZ number group lottery table shown in FIG. 41, the sub-flag lottery combination is “C bell” for any sub-flag lottery combination. Group D or number group H is selected.

<Distribution table when winning GG>
The GG winning allocation table shown in FIG. 45 represents an allocation number for determining the continuation rate of the winning GG.

  Specifically, in the GG winning allocation table, a distribution number for distributing a GG continuation rate (hereinafter simply referred to as “GG continuation rate”) is associated with the sub gaming state and the sub flag lottery combination. .

  For example, if the sub flag lottery role is “15 bells”, if the sub gaming state is not normally a GG precursor, the distribution number is determined as “13” and the sub gaming state is a GG precursor. Usually, if it is any of CZ1 to CZ4 or GG, “0” is determined as the allocation number, and if the sub gaming state is EG, SEG or PEG, “8” is determined as the allocation number.

<Gottery selection lottery table>
The GG winning allocation lottery table shown in FIG. 46 represents the probability that each GG continuation rate is determined for each allocation number determined when the GG is won. In the present embodiment, the GG continuation rate is “1% continuation”, “12.5% continuation”, “25% continuation”, “50% continuation”, “67 continuation”, “75% continuation”, and “80 % Continuation ".

  For example, when the distribution number is “8”, “1% continuation” is determined with a probability of 32592/32768, “50% continuation” is determined with a probability of 128/32768, and a probability of 32/32768 is “ “67% continuation” is determined, and “75% continuation” is determined with a probability of 16/32768.

<CZHOLD lottery table>
The CZHOLD lottery table shown in FIG. 47 is for each of the group numbers 1 to 6 (that is, HOLD winning A7, HOLD winning AV, HOLD winning AS, HOLD winning B7, HOLD winning BV, and HOLD winning BS). The probabilities of determining “without HOLD” and “with HOLD” are shown.

  The CZHOLD lottery table shown in FIG. 47 is set so that there is no HOLD when the group number is 1 to 3, and HOLD is present when the group number is 4 to 6. However, it may be set so that “without HOLD” and “with HOLD” are assigned to each of the outcome groups 1 to 6 with a predetermined probability.

<GZ winning rate lottery table after CZHOLD>
The GG winning rate lottery table after CZHOLD shown in FIG. 48 and FIG. 49 is the winning rate of GG in the next unit game when the sub-game state wins hold in any of CZ1 to CZ4 (that is, when HOLD is present). Represents.

  Specifically, the post-CZHOLD GG winning rate lottery table includes eight tables corresponding to the number group A to the number group H. Each post-CZHOLD GG winning rate lottery table represents a probability that a GG winning rate is determined for each sub-flag lottery combination. In the present embodiment, the GG winning rate is determined from among “20% winning”, “25% winning”, “33% winning”, “50% winning” and “100% winning”.

  For example, in the number group A, when the sub flag lottery role is “CU Bell”, “25% winning” is determined with a probability of 30080/32768, and “33% winning” is determined with a probability of 2048/32768. “50% winning” is determined with a probability of / 32768, and “100% winning” is determined with a probability of 128/32768.

<GG lottery table after CZHOLD>
The GG lottery table after CZHOLD shown in FIG. 50 has a GG non-winning and GG winning relative to the GG winning rate determined with reference to the GG winning rate lottery table after CZHOLD shown in FIGS. It represents the probability of being determined. For example, when the GG continuation rate is “20% winning”, the GG becomes non-winning with a probability of 26215/32768, and the GG becomes winning with a probability of 6553/32768.

<Rewind lottery table>
The rewind lottery table shown in FIG. 51 represents the probability of EG or PEG rewinding when the sub gaming state is EG, SEG or PEG.

  The rewind lottery table includes three tables corresponding to EG, SEG, and PEG. Each rewind lottery table represents the probability that EG or PEG rewind is determined for each sub-flag lottery combination.

  For example, when the sub gaming state is SEG and the sub flag lottery role is “C lip”, the rewinding is non-winning with a probability of 16384/32768, and the rewinding to the EG is with a probability of 8192/32768. Winning will be won, and rewinding to PEG will be winning with a probability of 8192/32768.

<Distribution table for rewinding win>
The rewinding / winning allocation table shown in FIG. 52 represents a distribution number for determining the continuation rate of the GG that has been won by the winning of rewinding.

  The rewinding win allocation table includes three tables corresponding to EG, SEG, and PEG. In each rewind winning allocation table, a distribution number for distributing the GG continuation rate is associated with the number of remaining games in each sub gaming state.

  For example, if the number of remaining EG games is 11G, “1” is determined as the distribution number, and if the remaining number of SEG games is 11G, “2” is determined as the distribution number, and the number of remaining PEG games is If it is 11G, “3” is determined as the distribution number.

<Rating lottery table for rewinding win>
The rewind winning allocation lottery table shown in FIG. 53 represents the probability that each GG continuation rate is determined for each allocation number determined when the rewind is won.

  For example, when the distribution number is “3”, “1% continuation” is determined with a probability of 32256/32768, “50% continuation” is determined with a probability of 500/32768, and “ “67% continuation” is determined, and “75% continuation” is determined with a probability of 4/32768.

<PEG promotion lottery table>
The PEG promotion table shown in FIG. 54 shows the probability that the sub game state is promoted from EG to PEG in the first unit game of EG or the first unit game after rewinding to EG when the sub game state is EG. Represents.

  Specifically, the PEG promotion lottery table shows the probability that PEG promotion non-winning and PEG promotion are determined with respect to the number of times of lottery for promotion from EG to PEG when the sub gaming state is EG. Represents.

  For example, in the first unit game (first time) of EG, the PEG promotion is non-winning with a probability of 32256/32768, and the PEG promotion is winning with a probability of 512/32768. In the first unit game after rewinding to the EG (after the second game), the PEG promotion is non-winning with a probability of 32640/32768, and the PEG promotion is winning with a probability of 128/32768.

<GG continuation rate lottery table during EG relief>
The EG continuation rate GG continuation rate lottery table shown in FIG. 55 represents the probability that each GG continuation rate is determined when GG is won during EG relief. For example, “50% continuation” is determined with a probability of 32864/32768, and “75% continuation” is determined with a probability of 4/32768.

<SEG addition game number lottery table>
The SEG addition game number lottery table shown in FIG. 56 includes two tables: a table when there is no SEG stock and a table when there is SEG stock.

  In each SEG extra game number lottery table, for each sub-flag lottery role, non-winning of the SEG game number is announced in the unit game (hereinafter also referred to as “immediate notice”), and It represents the probability that the number of added games to be stocked is determined. In the present embodiment, the number of additional games of SEG is determined from “10 games”, “20 games”, “30 games”, and “1000 games”.

  For example, if there is no SEG stock and the sub-flag lottery role is “C lip”, 10 games that will be immediately announced with a probability of 6848/32768 will be determined with a probability of 24576/32768. Twenty games to be notified immediately with a probability of 1024/32768 are determined, 30 games to be notified immediately with a probability of 256/32768 are determined, and 1000 games to be notified with a probability of 64/32768 are determined. In this case, the number of additional games to be stocked is not determined.

<History lottery table>
The history lottery tables shown in FIGS. 57 and 58 include five tables corresponding to the sub game states of normal, CZ1 and CZ2, CZ3 and CZ4, GG, EG, SEG and PEG.

  Each history lottery table represents the probability of winning GG and CZ1 to CZ4 for each history result. Here, the history results are “None”, “History Blue 3”, “History Blue 4”, “History Blue 5”, “History Yellow 3”, “History Yellow 4”, “History Yellow 5”. "Ream", "History white 5", "Special role 2 times within 5G", "Special role 3 times within 5G", "Special role 4 times within 5G", "Special role 5 times within 5G", It includes 16 results: "Red 7 within 5G twice", "Red 7 within 5G three times or more", "Red 7 two or more stations" and "GOD two times within 5G".

  Specifically, each history lottery table has “non-winning”, “GG winning”, “CZ1 winning”, “CZ2 winning”, “CZ3 winning”, “CZ4 winning”, “GG + CZ1” for each history result. It represents the probability determined to be “winning”.

  For example, when the sub gaming state is normal and the history result is “history blue triple”, “non-winning” is determined with a probability of 31130/32768, and “CZ1 winning” is with a probability of 1638/32768. Will be determined. Similarly, when the sub gaming state is normal and the history result is “history blue quadruple”, “CZ1 winning” is determined with a probability of 32768/32768.

  The history lottery table for EG, SEG, and PEG shown in FIG. 58 is shown as a common table, but the history lottery table for PEG is advantageous to the player over other history lottery tables. You may set so that addition of GG may be performed.

  In other words, the history lottery table for the sub gaming state other than PEG may be set such that the history lottery table for the sub gaming state PEG is more advantageous for the player.

  Specifically, the history lottery table may be set so that the winning probability of GG and CZ is higher when the sub gaming state is PEG than when the sub gaming state is other than PEG. .

[Main control processing]
The main CPU 93 of the main control board 41 executes various processes according to the flowcharts shown in FIGS.

<Main control processing>
FIG. 59 is a flowchart showing the main control process. The main control process described below starts when the pachislot machine 1 is powered on.

  First, when power is turned on to the pachi-slot machine 1, the main CPU 93 executes the power-on process shown in FIG. 60 (S10). In this power-on process, it is determined whether the backup is normal or the setting has been changed appropriately, and an initialization process is executed according to the determination result.

  Next, the main CPU 93 executes an initialization process at the end of one game (one unit game) (S11). In this initialization process, for example, a storage area designated in advance to be initialized at the end of one game is initialized. By this initialization process, data stored in the internal winning combination storing area, the display combining storage area, etc. of the main RAM 95 is cleared.

  Next, the main CPU 93 executes medal acceptance / start check processing shown in FIG. 61 (S12). In the medal acceptance / start check process, a process for detecting a medal inserted by the player and a process for detecting a start operation are executed.

  Next, the main CPU 93 extracts three random number values (random number values 1 to 3) and stores them in a random number storage area assigned to the main RAM 95 (S13). Here, the random value 1 is a value used for the internal lottery process, and is extracted from 0 to 65535 in the present embodiment.

  The random numbers 2 and 3 are values used for other lottery processing, and are extracted from 0 to 65535 and 0 to 255, respectively, in the present embodiment. The main CPU 93 does not always need to extract the random number values 2 and 3 in step S13, and may extract the random number values 2 and 3 only when the use occurs.

  Next, the main CPU 93 executes an internal lottery process shown in FIG. 62 (S14). The main CPU 93 that executes the internal lottery process constitutes an internal winning combination determining means.

  Next, the main CPU 93 executes a reel stop initial setting process shown in FIG. 64 (S16). By this reel stop initial setting process, each piece of information (for example, stop table number) relating to the reel stop control is stored in the corresponding area of the main RAM 95 based on the result of the internal lottery process (internal winning combination).

  Next, the main CPU 93 generates start command data to be transmitted from the main control board 41 to the sub control board 42, and stores the generated start command data in the communication data storage area assigned to the main RAM 95 (S17).

  The start command data represents, for example, a game state flag type, a bonus end number counter value, an internal winning combination type, an effect timer value, and the like.

  Next, the main CPU 93 executes a wait process (S18). In this wait process, it is determined whether or not a predetermined time has elapsed since the start of the previous game (start of the previous unit game), and if it is determined that the predetermined time has not elapsed, the predetermined time has elapsed. Wait until you are digested. The predetermined time in the wait process, that is, the wait time is set to 4.1 seconds from the start of the previous unit game, for example.

  Next, the main CPU 93 executes reel rotation start processing for rotating all the reels 3L, 3C, 3R according to the number of inserted medals (S19). With this reel rotation start process, “0000111” is stored in the operation stop button storage area (see FIG. 29).

  The reel rotation start process is executed by the interrupt process shown in FIG. This interrupt process is a process executed at a constant cycle (1.1172 ms). By this interruption process, the driving of the stepping motors 49L, 49C, 49R is controlled, and the rotation of the reels 3L, 3C, 3R is started.

  Thereafter, the driving of the stepping motors 49L, 49C, 49R is controlled by this interruption process, and the rotation of the reels 3L, 3C, 3R is accelerated until reaching a constant speed. Further, when the rotation of the reels 3L, 3C, 3R reaches a constant speed, the driving of the stepping motors 49L, 49C, 49R is controlled by this interruption process so that the reels 3L, 3C, 3R rotate at a constant speed. Maintained.

  Next, the main CPU 93 generates reel rotation start command data to be transmitted from the main control board 41 to the sub control board 42 and stores the generated reel rotation start command data in a communication data storage area assigned to the main RAM 95 ( S20).

  By receiving this reel rotation start command data, the sub-control board 42 can recognize the start of reel rotation, and can determine the timing for executing various effects.

  Next, the main CPU 93 executes a drawing priority order storage process shown in FIG. 65 (S21). In this pull-in priority storage process, the pull-in priority table selection process shown in FIG. 66 is executed, and the pull-in priority of all symbols of the reels 3L, 3C, 3R that are rotating is determined. That is, in the pull-in priority storage process, stop information is stored in the pull-in priority data storage area shown in FIG. 31 for each symbol position of each rotating reel based on the internal winning combination.

  For example, for each symbol of each reel 3L, 3C, 3R, if the corresponding symbol is permitted to stop, the drawing priority data is stored in the drawing priority data storage area based on the priority table, and the stop is not stopped. In the case of permission (for example, a case where an internal winning combination is won), data indicating suspension prohibition is stored in the drawing priority data storage area.

  Next, the main CPU 93 executes a reel stop control process shown in FIG. 68 (S22). By this process, the stop control of the reels 3L, 3C, 3R is performed. Next, the main CPU 93 executes a winning search process (S23).

  In this winning search process, after all the reels 3L, 3C, 3R are stopped, the symbol combination displayed on the activated winning line is checked against the symbol combination table, and the symbol combination displayed on the winning line is determined. To be judged.

  Specifically, the data stored in the symbol code storage area (see FIG. 26) and the data in the symbol combination tables (see FIGS. 11 to 13) are collated, and the collation result is stored in the display combination storage area. The

  More specifically, the data in the symbol code storage area is copied as it is into the display combination storage area. At this time, the payout number is obtained by referring to the symbol combination table. By the winning search process, the combination of symbols displayed on the display windows 4L, 4C, 4R is specified by stopping all the reels 3L, 3C, 3R.

  Next, the main CPU 93 executes payout of the number of medals according to the displayed symbol combination based on the result of the winning search process (S25). Along with this medal payout process, the control of the hopper device 43 and the update of the credit number are performed based on the payout number counter.

  Next, the main CPU 93 generates winning action command data to be transmitted from the main control board 41 to the sub control board 42, and stores the generated winning action command data in a communication data storage area assigned to the main RAM 95 (S26). . The winning operation command data represents, for example, the type of display combination, the number of medals paid out, and the like.

  Next, the main CPU 93 executes a bonus end check process shown in FIG. 69 (S27). By this bonus end check processing, processing for ending the operation of BB or RB is executed when the end condition of BB or RB is satisfied.

  Next, the main CPU 93 executes a bonus operation check process shown in FIG. 70 (S28). By this bonus operation check processing, processing for operating BB or RB based on the combination of symbols displayed by the reels 3L, 3C, 3R is executed. After executing the process of step S28, the main CPU 93 executes the process of step S11.

<Power-on processing>
FIG. 60 is a flowchart showing the power-on process executed in step S10 of the main control process shown in FIG.

  First, the main CPU 93 determines whether the backup is normal (S30). In this determination process, it is determined whether the backup is normal or not by error detection using the checksum value.

  For example, the main CPU 93 stores the set value of the pachislot machine 1 and the checksum value calculated from the set value when the power is turned off in the main RAM 95 as backup data, and the determination process when the power is turned on (S30). , The set value and the checksum value stored in the main RAM 95 are read out.

  Here, the main CPU 93 compares the checksum calculated from the read set value and the checksum that has been backed up, and determines that the backup is normal if the comparison results match.

  When determining that the backup is normal (YES), the main CPU 93 sets the backed up setting values and the like (S31). As a result, when the backup is normal, the set value before the power is turned off is set.

  After executing the process of step S31 or when determining that the backup is not normal in step S30 (NO), the main CPU 93 has the setting change switch provided in the cabinet 2a of the pachislot machine 1 turned on. Whether or not (S32). Here, if it is determined that the setting change switch is ON (YES), the main CPU 93 executes initialization processing at the time of setting change (S33).

  In the initialization process at the time of changing the setting, for example, the data stored in the internal winning combination storing area and the display winning combination storing area of the main RAM 95 are cleared and the set value is cleared.

  Next, the main CPU 93 generates initialization command data to be transmitted from the main control board 41 to the sub control board 42, and stores the generated initialization command data in the communication data storage area assigned to the main RAM 95 (S34). . The initialization command data represents, for example, whether or not a set value has been changed, a set value, and the like.

  Next, the main CPU 93 executes a set value change process (S35). In this setting value changing process, for example, the setting value is selected from 1 to 6 according to the operation result of the reset switch, and the setting value selected when the start lever 16 is operated is confirmed.

  Next, the main CPU 93 determines whether or not the setting change switch is in the on state (S36), and repeatedly executes the process of step S36 until a determination result that is not in the on state is obtained.

  Here, when a determination result that the setting change switch is not in the on state is obtained (NO), the main CPU 93 generates and generates initialization command data to be transmitted from the main control board 41 to the sub-control board 42. The initialization command data is stored in the communication data storage area assigned to the main RAM 95 (S37), and the power-on process is terminated.

  In step S32, when determining that the setting change switch is not on (NO), the main CPU 93 determines whether the backup is normal (S38). If it is determined that the backup is not normal (NO), the main CPU 93 executes an error process at power-on (S39).

  In power-on error processing, the main CPU 93 displays an error display or the like indicating that the backup is not normal. Note that the main CPU 93 does not release the error state depending on the operation of the stop release switch or the reset switch in the state where the backup is not normal (backup error), and a new setting change has been made. Only when the error state is cleared.

  If it is determined in step S38 that the backup is normal (YES), the main CPU 93 restores the state of the pachislot machine 1 to the state before the power is turned off based on the backup data stored in the main RAM 95. (S40), the power-on process is terminated.

<Medal reception / start check processing>
FIG. 61 is a flowchart showing the medal acceptance / start check process executed in step S12 of the main control process shown in FIG.

  First, the main CPU 93 determines whether or not there is an automatic insertion request (S50). When a replay role is won in the previous unit game, medals are automatically inserted in the current unit game. That is, in the determination process in step S50, it may be determined whether or not a replay combination has been won in the previous unit game.

  If the main CPU 93 determines in step S50 that there is an automatic loading request (YES), it executes an automatic loading process (S51). In the automatic insertion process, the same number of medals as the medals inserted in the previous unit game are automatically inserted.

  Subsequently, the main CPU 93 generates medal insertion command data to be transmitted from the main control board 41 to the sub control board 42 and stores the generated medal insertion command data in a communication data storage area assigned to the main RAM 95. A transmission process is executed (S52). Here, the medal insertion command data represents, for example, the presence / absence of medal insertion, the value of the inserted number counter, the value of the credit counter, and the like.

  In step S50, when the main CPU 93 determines that there is no automatic insertion request (NO), it accepts acceptance of medals (S53). For example, the main CPU 93 drives a solenoid of a selector (not shown) to form a path so that the medal inserted into the medal slot 13 passes through the selector.

  In step S50, when the main CPU 93 determines that there is an automatic insertion request (YES), the medal acceptance is prohibited from the previous unit game, so the processing related to the medal acceptance is performed. Does not execute.

  After the process of step S52 or S53 is executed, the main CPU 93 sets the maximum value of the number of inserted medals according to the gaming state (S54). In the present embodiment, the maximum value of the number of inserted medals is 3.

  Next, the main CPU 93 determines whether or not acceptance of medals is permitted (S55). If it is determined that the acceptance of medals is permitted (YES), the main CPU 93 executes a medal insertion check process for checking the number of inserted medals (S56). In this medal insertion check process, the value of the insertion number counter is updated according to the number of checked medals.

  Subsequently, the main CPU 93 generates medal insertion command data to be transmitted from the main control board 41 to the sub control board 42 and stores the generated medal insertion command data in a communication data storage area assigned to the main RAM 95. A transmission process is executed (S57).

  Next, the main CPU 93 determines whether or not medals can be inserted or credited (S58). In the present embodiment, the main CPU 93 satisfies the condition on condition that the number of inserted sheets is 3 and the credit is 50, or that the automatic loading process of step S51 is executed. Sometimes it is determined that a medal cannot be inserted or credited, and when the condition is not satisfied, it is determined that a medal can be inserted or credited.

  If it is determined in step S58 that medals cannot be inserted or credited (NO), the main CPU 93 prohibits the acceptance of medals (S59). For example, the main CPU 93 forms a path through which medals inserted into the medal insertion slot 13 are discharged from the medal payout opening 21 without driving the selector solenoid.

  If it is determined in step S55 that acceptance of medals is not permitted (NO), if it is determined in step S58 that medals can be inserted or credited (YES), or after the processing of step S59 is executed. The main CPU 93 determines whether or not the number of inserted medals is the number that can start the game (S60).

  That is, the main CPU 93 determines whether or not the number of medals inserted is a number that can start a unit game according to the gaming state. In the present embodiment, the main CPU 93 determines whether or not three medals have been inserted.

  Here, when it is determined that the number of inserted medals is not the number that can start the game (NO), the main CPU 93 executes the process of step S55. On the other hand, if it is determined that the number of inserted medals is the number that can start the game (YES), the main CPU 93 determines whether or not the start switch 64 is on (S61).

  If it is determined that the start switch 64 is not on (NO), the main CPU 93 executes the process of step S55. On the other hand, if it is determined that the start switch 64 is on (YES), the main CPU 93 prohibits medal acceptance (S62) and ends the medal acceptance / start check process.

<Internal lottery processing>
FIG. 62 is a flowchart showing the internal lottery process executed in step S14 of the main control process shown in FIG.

  First, the main CPU 93 sets an internal lottery table corresponding to the gaming state in the main RAM 95 (S80). Specifically, the main CPU 93 sets the internal lottery table shown in any of FIGS. 17 to 19 in the main RAM 95 according to the gaming state.

  Next, the main CPU 93 obtains a random value stored in the random value storage area (S81). Next, the main CPU 93 determines an internal winning combination based on the acquired random number value and the set internal lottery table, and stores it in the internal winning combination storing area (S82).

  Next, the main CPU 93 determines whether or not the value of the carryover combination storage area (see FIG. 27) is “0” (S83). In this determination processing, it is determined whether or not bit 7 corresponding to “BB” in the carryover storage area is set to “1”.

  If it is determined in step S83 that the value of the carryover combination storage area is not “0” (NO), the main CPU 93 ends the internal lottery process. On the other hand, when it is determined that the value of the carryover combination storage area is “0” (YES), the main CPU 93 determines the internal winning combination defined as the carryover combination among the internal winning combinations stored in the internal winning combination storage area. The combination (for example, BB) is stored in the carryover combination storage area (see FIG. 27) (S84). In the process of step S83, for example, when “BB” is acquired as the internal winning combination, bit 7 corresponding to “BB” in the carryover combination storing area is set to “1”.

  Subsequently, the main CPU 93 determines whether or not the value of the carryover combination storage area (see FIG. 27) is “0” (S85). In this determination processing, it is determined whether or not bit 7 corresponding to “BB” in the carryover storage area is set to “1”.

  If it is determined in step S85 that the value of the carryover combination storage area is “0” (YES), the main CPU 93 ends the internal lottery process. On the other hand, if it is determined that the value of the carryover combination storage area is not “0” (NO), the main CPU 93 executes the game state flag transition process shown in FIG. 63 (S76) and ends the internal lottery process.

<Game state flag transition process>
FIG. 63 is a flowchart showing the game state flag transition process executed in step S86 of the internal lottery process shown in FIG.

  First, the main CPU 93 determines whether or not BB is stored in the carryover combination storage area (see FIG. 27) (S90). In this process, it is determined whether or not bit 7 corresponding to “BB” in the carryover storage area is set to “1”.

  If it is determined in step S90 that BB is stored in the carryover combination storage area (YES), the main CPU 93 sets the RT1 gaming state as the RT gaming state (S91). In this process, the main CPU 93 sets the bit 4 corresponding to “RT1 gaming state” in the gaming state flag storage area (see FIG. 28) to “1”. After executing the process of step S91, the main CPU 93 ends the gaming state flag transition process.

  On the other hand, if it is determined in step S90 that BB is not stored in the carryover combination storage area (NO), the main CPU 93 ends the game state flag transition process.

<Reel stop initial setting process>
FIG. 64 is a flowchart showing the reel stop initial setting process executed in step S16 of the main control process shown in FIG.

  First, the main CPU 93 refers to the spinning cylinder stop initial setting table, and acquires the spinning cylinder stop number based on the internal winning combination or the like (S100). The rotation stop initial setting table is a table in which various information used for stop control is defined in association with the number of rotation stop corresponding to the number of throws and the internal winning combination.

  Next, the main CPU 93 refers to the spinning cylinder stop initial setting table and acquires each piece of information based on the spinning cylinder stop number (S101). In this process, the main CPU 93, for example, the number of the stop table used at the time of the first to third stops and the information necessary for performing the control change in the control change process (that is, the reels 3L, 3C, 3R are in a specific order) When the information is stopped at (1), information used for reselecting the stop table is acquired when the information is stopped (or pressed) at a specific position.

  The stop table stores information on the number of sliding pieces for the pressed position, either directly or indirectly. Using this information, there is a limit that does not cause a disadvantage to the player and does not cause an erroneous winning prize. Are configured to stop at a stop position intended by the developer.

  Subsequently, the main CPU 93 stores the rotating identifier in the symbol code storage area (see FIG. 26) (S102). That is, the main CPU 93 sets the bits of all symbol code storage areas (excluding unused areas) to “1”.

  Next, the main CPU 93 stores 3 in the stop button non-operation counter (S103) and ends the reel stop initial setting process. The stop button non-operating counter is used for determining the number of stop buttons 17L, 17C, and 17R that are not stopped by the player, and is stored in a predetermined area of the main RAM 95.

<Retrieve priority storage process>
FIG. 65 is a flowchart showing the pull-in priority storage process executed in step S21 of the main control process shown in FIG. 59 and step S165 of the reel stop control process shown in FIG.

  First, the main CPU 93 stores the value of the stop button non-operating counter as the number of searches in the main RAM 95 (S110). Next, the main CPU 93 executes a search target reel determination process for determining a search target reel (S111). In this process, among the rotating reels, for example, one reel on the left side is determined as a search target reel.

  Next, the main CPU 93 executes a pull-in priority table selection process shown in FIG. 66 (S112). In this pull-in priority table selection process, one pull-in priority table number is selected from the pull-in priority table (see FIG. 21).

  Next, the main CPU 93 sets 20 (the number of symbols on each reel) to the number of symbol checks stored in the main RAM 95, and sets 0 to the symbol position to be searched (S113).

  Next, the main CPU 93 executes a symbol code storing process shown in FIG. 67 (S114). In the symbol code storage process, a symbol code of the symbol position data for checking for checking the symbol position of the rotating reel is acquired.

  Next, the main CPU 93 updates the display combination storing area (see FIG. 25) based on the acquired symbol code and the symbol code storing area (see FIG. 26) (S115). Next, the main CPU 93 executes a pull-in priority data acquisition process (S116).

  In this pull-in priority data acquisition process, in step S112, the corresponding bit is 1 in the display combination storing area and the corresponding bit is 1 in the internal winning combination storing area (see FIG. 24). With reference to the selected pull-in priority table, pull-in priority data is acquired.

  In the drawing priority order data acquisition process, “stop prohibition” (000H) is set for the symbol positions that are erroneously won when stopped, and no internal winnings are made. For the symbol position, “stoppable” (001H) is set.

  Next, the main CPU 93 stores the acquired drawing priority data in the drawing priority data storage area corresponding to the search target reel (S117). Next, the main CPU 93 subtracts 1 from the number of symbol checks, and adds 1 to the retrieved symbol position (S118).

  Next, the main CPU 93 determines whether or not the number of symbol checks is 0 (S119). Here, when it is determined that the number of symbol checks is not 0 (NO), the main CPU 93 executes the process of step S114.

  On the other hand, when it is determined that the number of symbol checks is 0 (YES), the main CPU 93 determines whether or not a search for the number of searches has been executed (S120). If it is determined that the search for the number of times of search has been executed (YES), the main CPU 93 ends the pull-in priority storage process. On the other hand, if it is determined that the search for the number of times of search has not been executed (NO), the main CPU 93 executes the process of step S111.

<Pull-in priority table selection processing>
FIG. 66 is a flowchart showing a pull-in priority table selection process executed in step S112 of the pull-in priority storage process shown in FIG.

  First, the main CPU 93 determines whether or not pull-in priority table selection data is set (S130). If it is determined that the pull-in priority table selection data is set (YES), the main CPU 93 refers to the pressing order storage area (see FIG. 30) and the operation stop button storage area (see FIG. 29). Then, a drawing priority table number corresponding to the drawing priority table selection data is set from the drawing priority table selection table (not shown) (S131), and a drawing priority table corresponding to the drawing priority table number is set ( S132), the pull-in priority table selection process is terminated.

  On the other hand, if it is determined that the pull-in priority table selection data is not set (NO), the main CPU 93 sets a pull-in priority table corresponding to the pull-in priority table number (S132), and the pull-in priority table The selection process ends.

<Design code storage processing>
FIG. 67 is a flowchart showing the symbol code storing process executed in step S114 of the drawing priority order storing process shown in FIG. 65 and in step S159 of the reel stop control process shown in FIG.

  First, the main CPU 93 sets valid line data (S140). In the present embodiment, the main CPU 93 sets a center line as an effective line. Next, the main CPU 93 sets check symbol position data for the search target reel based on the search symbol position and the effective line data (S141). In the present embodiment, the main CPU 93 sets the middle symbol position of the left reel 3L as check symbol position data.

  Next, the main CPU 93 acquires the symbol code of the symbol position data for check (S142), and ends the symbol code storage process.

<Reel stop control process>
FIG. 68 is a flowchart showing the reel stop control process executed in step S22 of the main control process shown in FIG.

  First, the main CPU 93 determines whether or not a valid stop button has been pressed (S150). This process is a process for determining whether or not a signal is output from the stop switch 7S. If the main CPU 93 determines that a valid stop button has not been pressed (NO), the main CPU 93 repeatedly executes the process of step S150.

  On the other hand, when the main CPU 93 determines that a valid stop button has been pressed (YES), the main CPU 93 determines the pressing order storage area (see FIG. 30) and the operation stop button storage area (see FIG. 30) according to the pressed stop button. 29) is updated (S151).

  Here, the main CPU 93 stores the type of the operation stop button corresponding to each of the first stop operation, the second stop operation, and the third stop operation in the pressing order storage area (see FIG. 30). , It is possible to determine the pressing order of the stop buttons 17L, 17C, and 17R.

  Subsequently, the main CPU 93 subtracts 1 from the stop button non-operation counter (S152), determines a search target reel from the operation stop button (S153), and stores the stop start position in the main RAM 95 based on the symbol counter (S153). S154). The stop start position is a symbol position corresponding to the symbol counter of the reel when the stop operation is detected by the stop switch 7S.

  Next, the main CPU 93 executes a sliding piece number determination process (S155). In this sliding piece number determination process, the number of sliding pieces defined at the stop start position is determined based on the stop table selection data group selected based on the internal winning combination from the turning stop initial setting table (see FIG. 20). It is processing to do.

  Next, the main CPU 93 generates reel stop command data to be transmitted from the main control board 41 to the sub control board 42, and stores the generated reel stop command data in the communication data storage area assigned to the main RAM 95. A transmission process is executed (S156). This reel stop command data represents the type of reel to be stopped, the stop start position, the number of sliding pieces (or planned stop position), and the like.

  Next, the main CPU 93 determines a planned stop position based on the stop start position and the sliding piece number determination data, and stores it in the main RAM 95 (S157). The scheduled stop position is a symbol position obtained by adding any of predetermined numerical values “0” to “4” defined as the number of sliding pieces to the stop start position, and the symbol position where the reel rotation stops. It is.

  Next, the main CPU 93 sets the planned stop position as a search symbol position (S158). Next, the main CPU 93 executes a symbol code storing process shown in FIG. 67 (S159).

  Next, the main CPU 93 updates the symbol code storage area from the symbol code acquired in the symbol code storage process (S160). Next, the main CPU 93 performs a control change process (S161). In this control change process, the reel stop information group is updated when a specific stop position is reached.

  Next, the main CPU 93 determines whether or not the pressed stop button has been released (S162). This process is a process for determining whether or not a signal is no longer output from the stop switch 7S.

  When determining that the pressed stop button has not been released (NO), the main CPU 93 repeatedly executes the process of step S162. On the other hand, when determining that the pressed stop button has been released (YES), the main CPU 93 executes a reel stop command transmission process (S163).

  The reel stop command generated by this reel stop command transmission process includes information about the ON edge / OFF edge of the stop switch 7S. The ON edge / OFF edge information may be monitored by an interrupt process and transmitted to the sub-control board 42.

  Next, the main CPU 93 determines whether or not the stop button non-operation counter is 0 (S164). Here, when it is determined that the stop button non-operation counter is not 0 (NO), the main CPU 93 executes the pull-in priority storage process shown in FIG. 65 (S165), and executes the process of step S150. On the other hand, when it is determined that the stop button non-operation counter is 0 (YES), the main CPU 93 ends the reel stop control process.

<Bonus end check process>
FIG. 69 is a flowchart showing the bonus end check process executed in step S27 of the main control process shown in FIG.

  First, the main CPU 93 determines whether or not the main gaming state is the BB operating state, that is, whether or not the BB operating state flag stored in the gaming state flag storage area shown in FIG. 28 is ON (S280).

  If it is determined that the main game state is not the BB operation state (NO), the main CPU 93 ends the bonus end check process. On the other hand, when determining that the main game state is the BB operation state (YES), the main CPU 93 updates the bonus end number counter (S281). Next, the main CPU 93 determines whether or not the value of the bonus end number counter is smaller than “0” (S282).

  If the value of the bonus end number counter is smaller than “0” (YES), the main CPU 93 executes a BB end process for turning off the BB operation state flag (S283).

  Next, the main CPU 93 sets the RT0 gaming state as the RT gaming state (S284). In this process, the main CPU 93 sets bit 5 corresponding to “RT0 gaming state” in the gaming state flag storage area (see FIG. 28) to “1”.

  Thereafter, the main CPU 93 generates bonus end command data to be transmitted from the main control board 41 to the sub-control board 42, and stores the generated bonus end command data in a communication data storage area assigned to the main RAM 95. The process is executed (S285), and the bonus end check process ends.

  On the other hand, if the value of the bonus end number counter is not smaller than “0” in step S282, that is, if the value of the bonus end number counter is not less than “0” (NO), the main CPU 93 The value of the possible game counter is decremented by “1” (step S286).

  Next, the main CPU 93 determines whether or not the values of the winning number counter and the possible game number counter are “0” (step S287). When the values of the winning number counter and the possible game number counter are not “0”, the main CPU 93 ends the bonus end check process.

  On the other hand, when the values of the winning number counter and the possible game number counter are “0”, the main CPU 93 executes RB end processing for turning off the RB operation state flag (step S289), and bonus end check processing. Exit.

<Bonus activation check process>
FIG. 70 is a flowchart showing the bonus operation check process executed in step S28 of the main control process shown in FIG.

  First, the main CPU 93 determines whether or not the main gaming state is the BB gaming state (S290). Here, when it is determined that the main gaming state is the BB gaming state (YES), the main CPU 93 determines whether or not the RB is operating (step S291).

  If it is determined that the RB is in operation (YES), the main CPU 93 ends the bonus operation check process. On the other hand, if it is determined that the RB is not in operation (NO), an RB operation process for operating the RB is executed (step S292), and the bonus operation check process is terminated. In the RB operation process, the main CPU 93 turns on the RB game state flag, sets “1” to the winning number counter, and sets “1” to the possible game number counter, for example.

  On the other hand, if it is determined in step S290 that the main gaming state is not the BB gaming state (NO), the main CPU 93 determines that the combination of “lower half circle—upper half circle—blue 7A” corresponding to “BB” is valid. It is determined whether or not the image is displayed along the line (step S293).

  When it is determined that the combination of “lower half circle-upper half circle-blue 7A” corresponding to “BB” is displayed along the active line (YES), the main CPU 93 performs BB operation processing for operating BB. It executes (step S292). In the BB operation process, the main CPU 93 turns on the BB gaming state flag and sets a predetermined number (for example, 86) in the bonus end number counter. At this time, the main CPU 93 also performs the RB operation process described above.

  Next, the main CPU 93 clears the value of the carryover combination storage area (S295). Thereafter, the main CPU 93 generates bonus start command data to be transmitted from the main control board 41 to the sub control board 42, and stores the generated bonus start command data in a communication data storage area allocated to the main RAM 95. The process is executed (S296), and the bonus operation check process is terminated.

  On the other hand, if it is determined in step S293 that the combination of “lower semicircle-upper semicircle-blue 7A” corresponding to “BB” is not displayed along the active line (NO), one of the replays is performed. Whether or not is displayed is determined (step S297).

  If it is determined that any of the replays has not been displayed (NO), the main CPU 93 ends the bonus operation check process. On the other hand, if it is determined that any of the replays is displayed (YES), the main CPU 93 issues an automatic insertion request so that the automatic insertion process is executed in S51 of the medal acceptance / start check process shown in FIG. (S298), and the bonus operation check process is terminated.

<Interrupt processing under main CPU control>
FIG. 71 is a flowchart showing an interrupt process under the control of the main CPU 93. This process is executed every 1.1172 milliseconds.

  First, the main CPU 93 saves the register (S320). Next, the main CPU 93 executes an input port check process shown in FIG. 72 (S321). In this process, the main CPU 93 confirms the presence / absence of a signal transmitted to the sub control board 42.

  For example, the main CPU 93 stores input state command data representing on-edge and off-edge information of various switches including the on-edge and off-edge of the start switch 64 and stop switch 7S in the communication data storage area of the main RAM 95.

  Next, the main CPU 93 executes timer update processing (S322). Subsequently, the main CPU 93 executes an effect timer update process (S323). Next, the main CPU 93 executes a reel control process for controlling the rotation of the reels 3L, 3C, 3R (S324).

  More specifically, the main CPU 93 starts the rotation of the reels 3L, 3C, and 3R in response to a request for starting the rotation of the reels 3L, 3C, and 3R, that is, in response to the start operation. Control is performed so that 3L, 3C, and 3R rotate. Further, the main CPU 93 performs control so that the rotation of the reels 3L, 3C, and 3R corresponding to the stop operation stops in response to the stop operation.

  Next, the main CPU 93 executes a lamp / 7SEG driving process (S325). For example, the main CPU 93 displays the number of credited medals, the number of payouts, etc. on various display units. Next, the main CPU 93 restores the register (S326), and terminates the interrupt process that occurs periodically.

<Input port check processing>
FIG. 72 is a flowchart showing the input port check process executed in step S321 of the interrupt process under the control of the main CPU 93.

  First, the main CPU 93 checks the state of each input port (S330). Next, the main CPU 93 stores the previous interrupt, that is, the state of the input port before one interrupt in the main RAM 95 (S331), and stores the current input port state in the main RAM 95 (S332).

  As described above, the main CPU 93 can check the states of both input ports by comparing the state of the input port before one interrupt with the current state of the input port. Thus, it is checked whether the state of the input port has changed, for example, whether the MAX bet button 14 or the 1 bet button 15 has been pressed.

  Next, the main CPU 93 stores the on-edge state in the main RAM 95 (S333). In the present embodiment, the on-edge refers to a state where the button is pressed, and the off-edge refers to a state where the button is released.

  Next, the main CPU 93 generates input state command data to be transmitted from the main control board 41 to the sub control board 42, and stores the generated input state command data in a communication data storage area allocated to the main RAM 95. The transmission process is executed (S334), and the input port check process is terminated.

[Sub-control processing]
The sub CPU 102 of the sub control board 42 executes various processes according to the flowcharts shown in FIGS.

<Power-on processing>
FIG. 73 is a flowchart showing power-on processing of the sub CPU 102 at power-on.

  First, the sub CPU 102 executes an initialization process (S350). In this process, the sub CPU 102 performs error check of the sub RAM 103 and the like, and initializes the task system. The task system includes a lamp control task, a sound control task, which are timer interrupt synchronization task groups, and a mother task, which is a VSYNC (Vertical Synchronization) interrupt synchronization task group.

  Next, the sub CPU 102 activates the lamp control task shown in FIG. 74 (S351). The lamp control task waits for the sub CPU 102 to receive a timer interrupt event message transmitted to the sub CPU 102 every 2 milliseconds, and in response to receiving the timer interrupt event message, It is a process which performs the process which controls a lighting state.

  Next, the sub CPU 102 activates the sound control task shown in FIG. 75 (S352). In the sound control task, the sub CPU 102 controls the sound output state from the speakers 23L and 23R.

  Next, the sub CPU 102 activates the mother task (S353) and ends the power-on process. The mother task is a task group for VSYNC (vertical synchronization signal) interrupt synchronization, and a vertical synchronization signal (VSYNC interrupt signal) sent from the liquid crystal display device 11 when an image of one frame is displayed on the liquid crystal display device 11. Is used.

<Ramp control task>
FIG. 74 is a flowchart showing the lamp control task activated in step S351 of the power-on process shown in FIG.

  First, the sub CPU 102 executes a timer interrupt initialization process (S360). Next, the sub CPU 102 executes initialization processing of lamp related data (S361).

  Next, the sub CPU 102 waits for a timer interrupt (S362). In this process, until the sub CPU 102 receives a timer interrupt event message every 2 milliseconds, the sub CPU 102 executes a task group different from the timer interrupt synchronization.

  As a task group different from timer interrupt synchronization, for example, a main board communication task which is a task group for command reception interrupt synchronization can be cited. Moreover, a task group (not shown) for power supply interrupt synchronization, a task group (not shown) for door monitoring unit communication synchronization, and the like can be given.

  Next, the sub CPU 102 executes the sound control task shown in FIG. 75 (S363). In this process, the task in the next priority of the timer interrupt synchronization task group which is the same group as the lamp control task is executed.

  In this embodiment, the priority order of the task group for timer interrupt synchronization is basically the order of the lamp control task and the sound control task. Therefore, in step S363, the sound control task at the next priority of the lamp control task is executed. In step S363, the processes of steps S372 and S373 are executed in the sound control task shown in FIG.

  Next, the sub CPU 102 executes a lamp data analysis process (S364), executes a lamp effect execution process (S365), and executes the process of step S362.

<Sound control task>
FIG. 75 is a flowchart showing the sound control task activated in step S352 of the power-on process shown in FIG.

  First, the sub CPU 102 executes an initialization process of sound related data related to the sound output state from the speakers 23L and 23R (S370). Next, the sub CPU 102 executes a task in the next priority of the task group for timer interrupt synchronization that is the same group as the sound control task, that is, the lamp control task (S371).

  Next, the sub CPU 102 executes sound data analysis processing (S372), performs sound effect execution processing (S373), and executes processing in step S371.

<Mother task>
FIG. 76 is a flowchart showing the mother task activated in step S353 of the power-on process shown in FIG.

  In the mother task, the sub CPU 102 activates the main task (S380), activates the main board communication task (S381), and activates the animation task (S382).

<Main task>
FIG. 77 is a flowchart showing the main task activated in step S380 of the mother task shown in FIG.

  In the main task, the sub CPU 102 executes a VSYNC interrupt initialization process (S390) and waits for a VSYNC interrupt (S391). Next, the sub CPU 102 executes a drawing process (S392), and executes the process of step S391.

<Main board communication task>
FIG. 78 is a flowchart showing the main board communication task activated in step S381 of the mother task shown in FIG.

  First, the sub CPU 102 executes initialization of the communication message queue (S400), and checks the received command (S401).

  Next, the sub CPU 102 determines whether or not a valid command has been received (S402). If it is determined that a valid command has not been received (NO), the sub CPU 102 executes the process of step S401.

  On the other hand, if it is determined that a valid command has been received (YES), the sub CPU 102 creates game information from the received command and stores the created game information in the sub RAM 103 (S403). Next, the sub CPU 102 executes a command analysis process shown in FIG. 79 (S404), and executes the process of step S401.

<Command analysis processing>
FIG. 79 is a flowchart showing command analysis processing executed in step S404 of the main board communication task shown in FIG.

  First, the sub CPU 102 executes an effect content determination process shown in FIG. 81 (S410), executes a ramp data determination process (S411), executes a sound data determination process (S412), and registers each determined data. In step S413, the command analysis process is terminated.

<Anime task>
FIG. 80 is a flowchart showing the animation task activated in step S382 of the mother task shown in FIG.

  First, the sub CPU 102 checks a change from the previous game information (S420). Specifically, the sub CPU 102 indicates that the current game information updated by the interrupt processing under the control of the main CPU 93 shown in FIG. 71 is the game information registered in the sub RAM 103 in the previous interrupt processing. Check if the game information is different.

  Next, the sub CPU 102 executes object control processing (S421). Specifically, when a check result indicating that the game information has changed is obtained in step S420, the sub CPU 102 controls the image according to the change in the game information.

  Subsequently, the sub CPU 102 executes animation task management processing (S422). Specifically, the sub CPU 102 manages the order of images displayed in various effects. When executing the animation task management process, the sub CPU 102 executes the process of step S420.

<Production content determination process>
FIG. 81 is a flowchart showing effect content determination processing executed in step S410 of the command analysis processing shown in FIG.

  First, the sub CPU 102 determines whether or not an initialization command has been received (S430). If it is determined that the initialization command has been received (YES), the sub CPU 102 executes the initialization command reception process (S431), and ends the effect content determination process. In the initialization command reception process, for example, effect data based on information transmitted as an initialization command including whether or not the setting value has been changed and information on the setting value is set in the sub-RAM 103.

  On the other hand, if it is determined that the initialization command has not been received (NO), the sub CPU 102 determines whether or not a medal insertion command has been received (S432). If it is determined that a medal insertion command has been received (YES), the sub CPU 102 executes a medal insertion command reception process (S433), and ends the effect content determination process.

  In the medal insertion command reception process, for example, effect data is set based on information transmitted as a medal insertion command, including the presence / absence of medal insertion and the values of the inserted number counter and credit counter.

  On the other hand, if it is determined that a medal insertion command has not been received (NO), the sub CPU 102 determines whether or not a start command has been received (S434). If it is determined that a start command has been received (YES), the sub CPU 102 executes a start command reception process shown in FIG. 82 (S435), and ends the effect content determination process.

  In the process at the time of receiving the start command, for example, it is transmitted as a start command including the type of gaming state flag, the value of the bonus end number counter, the type of internal winning combination, the type of flag related to locking, etc., the value of the effect timer, etc. Production data based on the received information is set.

  On the other hand, if it is determined that a start command has not been received (NO), the sub CPU 102 determines whether a reel rotation start command has been received (S436). If it is determined that a reel rotation start command has been received (YES), the sub CPU 102 executes a reel rotation start command reception process (S437), and ends the effect content determination process. In the reel rotation start command reception process, for example, effect data based on information transmitted as a reel rotation start command indicating that the reel rotation has started is set.

  On the other hand, when it is determined that the reel rotation start command has not been received (NO), the sub CPU 102 determines whether or not a reel stop command has been received (S438). If it is determined that a reel stop command has been received (YES), the sub CPU 102 executes a reel stop command reception process shown in FIG. 88 (S439), and ends the effect content determination process.

  In the reel stop command reception process, for example, effect data based on information transmitted as a reel stop command including the type of stop reel, the stop start position, the number of sliding frames (or the planned stop position), and the like are set.

  On the other hand, if it is determined that the reel stop command has not been received (NO), the sub CPU 102 determines whether or not a winning operation command has been received (S440). If it is determined that a winning action command has been received (YES), the sub CPU 102 executes a winning action command reception process (S441), and ends the effect content determination process.

  In the process at the time of receiving a winning action command, for example, effect data based on information transmitted as a winning action command is set, including the type of display combination, a flag related to locking, the number of medals paid out, and the like.

  On the other hand, if it is determined that the winning operation command has not been received (NO), the sub CPU 102 determines whether or not a bonus start command has been received (S442). If it is determined that a bonus start command has been received (YES), the sub CPU 102 executes a bonus start command reception process (S443), and ends the effect content determination process. In the process at the time of receiving the bonus start command, for example, effect data based on information transmitted as a bonus start command indicating that the bonus has been started is set.

  On the other hand, if it is determined that the bonus start command has not been received (NO), the sub CPU 102 determines whether or not a bonus end command has been received (S444). If it is determined that a bonus end command has been received (YES), the sub CPU 102 executes a bonus end command reception process (S445), and ends the effect content determination process. In the bonus end command reception process, for example, effect data based on information transmitted as a bonus end command indicating that the bonus has ended is set.

  On the other hand, if it is determined that a bonus end command has not been received (NO), the sub CPU 102 determines whether an input state command has been received (S446). If it is determined that an input state command has been received (YES), the sub CPU 102 executes an input state command reception process (S447), and ends the effect content determination process.

  In input state command reception processing, for example, effect data based on information transmitted as an input state command indicating whether each operation unit is in an on-edge state or an off-edge state is set. On the other hand, if it is determined in S446 that the input state command has not been received (NO), the sub CPU 102 ends the effect content determination process.

<Processing when receiving a start command>
FIG. 82 is a flowchart showing a start command reception process executed in step S435 of the effect content determination process shown in FIG.

  First, the sub CPU 102 determines whether or not the gaming state controlled by the main CPU 93 is a BB carryover state (S450). If it is determined that the gaming state controlled by the main CPU 93 is not the BB carry-over state (NO), the sub CPU 102 ends the start command reception process.

  On the other hand, if it is determined that the gaming state controlled by the main CPU 93 is the BB carryover state (YES), the sub CPU 102 executes lottery pre-processing shown in FIG. 83 (S451).

  Next, the sub CPU 102 determines whether or not the sub gaming state is any one of CZ1 to CZ4 (S452). Here, when it is determined that the sub gaming state is any one of CZ1 to CZ4 (YES), the sub CPU 102 executes the in-CZ process shown in FIGS. 86 and 87 (S453).

  On the other hand, when it is determined that the sub game state is not any of CZ1 to CZ4 (NO), the sub CPU 102 determines whether or not the sub game state is EG (S454). Here, if it is determined that the sub gaming state is EG (YES), the sub CPU 102 executes the EG processing shown in FIGS. 93 to 95 (S455).

  On the other hand, if it is determined that the sub gaming state is not EG (NO), the sub CPU 102 determines whether or not the sub gaming state is SEG (S456). Here, when it is determined that the sub gaming state is SEG (YES), the sub CPU 102 executes the SEG in-process shown in FIGS. 96 and 97 (S457).

  On the other hand, if it is determined that the sub gaming state is not SEG (NO), the sub CPU 102 determines whether or not the sub gaming state is PEG (S458). Here, if it is determined that the sub gaming state is PEG (YES), the sub CPU 102 executes the in-PEG processing shown in FIGS. 98 and 99 (S459).

  On the other hand, if it is determined that the sub game state is not PEG (NO), the sub CPU 102 determines whether or not the sub game state is GG (S460). Here, if it is determined that the sub gaming state is GG (YES), the sub CPU 102 executes the GG in-process shown in FIG. 100 (S461). On the other hand, if it is determined that the sub gaming state is not GG (NO), the sub CPU 102 executes the common processing shown in FIGS. 101 and 102 (S462).

  After executing the process of steps S453, S455, S457, S459, S461, or S462b, the sub CPU 102 executes the common lottery process shown in FIG. 107 (S463), and executes the lottery post-process shown in FIG. 108 (S464). The process at the time of receiving the start command is terminated.

<Lottery pretreatment>
FIG. 83 is a flowchart showing the lottery pre-processing executed in step S451 of the start command reception processing shown in FIG.

  First, the sub CPU 102 sets the next game state representing the sub game state determined in the previous game as the sub game state (S470). Next, the sub CPU 102 clears the CZ hold GG winning flag (S472).

  Next, the sub CPU 102 determines whether or not the sub gaming state is EG (S473). If it is determined that the sub gaming state is not EG (NO), the sub CPU 102 sets an EG relief flag (S474).

  On the other hand, when it is determined that the sub gaming state is EG (YES), or after executing the process of step S474, the sub CPU 102 sets the main flag corresponding number corresponding to the internal winning combination to the sub flag corresponding to the sub gaming state. While converting into a conversion number, the subflag conversion process which converts a subflag conversion number into the subflag lottery number for lottery is performed (S475).

  In the flag conversion process, the sub CPU 102 refers to the sub flag conversion table shown in FIG. 32, identifies the sub flag conversion number associated with the main flag corresponding number, and converts the sub flag state by conversion table shown in FIGS. The sub flag conversion number is converted by lottery with a probability corresponding to the sub game state.

  Further, in the flag conversion process, the sub CPU 102 refers to the sub flag lottery conversion table shown in FIG. 40 and identifies the sub flag lottery number associated with the sub flag conversion number.

  After executing the processing of S475, the sub CPU 102 executes the CZ counter processing shown in FIGS. 84 and 85 (S476). Next, the sub CPU 102 determines whether or not the number of GG precursor games representing the number of unit games from winning the GG to activating the GG is 0 or more (S477).

  If it is determined that the number of GG precursor games is 0 or more, the sub CPU 102 subtracts 1 from the number of GG precursor games (S478). If it is determined in step S477 that the number of GG precursor games is not 0 or more, or after executing the process of step S478, the sub CPU 102 ends the lottery pre-process.

<CZ counter processing>
84 and 85 are flowcharts showing the CZ counter process executed in step S476 of the lottery pre-process shown in FIG.

  First, the sub CPU 102 determines whether or not the sub game state is the first game of CZ1 to CZ4, GG, EG, SEG or PEG (S480). Here, if it is determined that the sub gaming state is the first game of CZ1 to CZ4, GG, EG, SEG or PEG (YES), the sub CPU 102 initializes the normal CZ number precursor counter (for example, The value is set to “−1”) (S481), and the number of CZ precursor games in the GG is initialized (for example, “−1” is set) (S482).

  In step S480, when it is determined that the sub game state is not the first game of CZ1 to CZ4, GG, EG, SEG or PEG (NO), or after executing the process of step S482, the sub CPU 102 performs the normal CZ It is determined whether or not the value of this precursor counter is 0 (S483).

  If it is determined that the value of the normal CZ number precursor counter is not 0 (NO), the sub CPU 102 determines whether or not the value of the normal CZ number precursor counter is 1 or more (S484). . When it is determined that the value of the normal CZ precursor sign is 1 or more (YES), the sub CPU 102 has the sub flag conversion number 0 or 1 (that is, the sub flag conversion role name is lost or “bell spilling”). Whether or not (S485).

  If it is determined in step S483 that the value of the normal CZ count precursor counter is 0 (YES), or if it is determined in step S485 that the subflag conversion number is 0 or 1 (YES), The CPU 102 causes the normal medium CZ book precursor counter to subtract one value (S486).

  If it is determined in step S484 that the value of the normal CZ precursor counter is not 1 or more (NO), if it is determined in step S485 that the subflag conversion number is neither 0 or 1 (NO), or After executing the processing of S486, the sub CPU 102 determines whether or not the number of CZ pre-game games in the GG is 0 or more (S487).

  If it is determined that the number of CZ pre-game games in GG is 0 or more (YES), the sub CPU 102 determines whether the sub flag conversion number is 25 (that is, the sub flag conversion combination name is “GOD”). Is determined (S488). Here, if it is determined that the sub flag conversion number is not 25 (NO), the sub CPU 102 subtracts 1 from the number of normal CZ precursor games (S489).

  If it is determined in step S487 that the number of CZ pre-games in GG is not 0 or more (NO), if it is determined in step S488 that the sub-flag conversion number is 25 (YES), or the process of step S489 is executed. After that, the sub CPU 102 determines whether or not the sub gaming state is normal (S490).

  If it is determined that the sub gaming state is normal (YES), the sub CPU 102 determines whether CZ1 or CZ2 is present in the CZ information stock (S491). If it is determined that there is CZ1 or CZ2 in the CZ information stock (YES), the sub CPU 102 determines whether or not the number of GG predecessor games is 0 or more (S492).

  If it is determined in step S492 that the number of GG precursor games is not equal to or greater than 0 (NO), the sub CPU 102 determines whether or not CZ1 or CZ2 is in progress (S493).

  If it is determined that the sign of CZ1 or CZ2 is not in progress (NO), the sub CPU 102 performs a normal medium CZ precursor counter lottery in which the value of the normal medium CZ precursor counter is determined by lottery (S494).

  In the normal CZ precursor counter lottery, for example, the sub CPU 102 randomly determines one value from a range of 1 to 16. Next, the sub CPU 102 sets the result of the normal medium CZ precursor counter lottery to the normal medium CZ precursor counter (S495).

  If it is determined in step S490 that the sub gaming state is not normal (NO), or if it is determined in step S491 that neither CZ1 nor CZ2 is present in the CZ information stock (NO), then the number of GG precursor games in step S492. Is determined to be greater than or equal to 0 (YES), if it is determined in step S493 that CZ1 or CZ2 is being detected (YES), or after executing the process of step S495, the sub CPU 102 It is determined whether or not the state is GG (S496).

  If it is determined that the sub game state is not GG (NO), the sub CPU 102 ends the CZ counter process. On the other hand, if it is determined that the sub gaming state is GG (YES), the sub CPU 102 determines whether CZ3 or CZ4 is present in the CZ information stock (S497).

  If it is determined that there is no CZ3 or CZ4 in the CZ information stock (NO), the sub CPU 102 determines whether or not the sub flag conversion number is 25 (that is, the sub flag conversion combination name is “GOD”) (S498). . If it is determined that the sub flag conversion number is not 25 (NO), the sub CPU 102 determines whether or not a sign of CZ3 or CZ4 is in progress (S499).

  If it is determined that the sign of CZ3 or CZ4 is not in progress (NO), the sub CPU 102 performs the GG CZ precursor game number lottery for lottering the number of CZ precursor games in GG (S500). In the GG medium CZ precursor game number lottery, for example, the sub CPU 102 randomly determines one value from a range of 1 to 32. Next, the sub CPU 102 sets the result of the GG CZ precursor game number lottery to the CZ CZ precursor game number (S501).

  If it is determined in step S496 that the sub gaming state is not GG (NO), or if it is determined in step S497 that neither CZ3 nor CZ4 is present in the CZ information stock (NO), the subflag conversion number is 25 in step S498. Is determined (YES), in step S499, it is determined that CZ3 or CZ4 is in the precursor (YES), or after executing the process of step S501, the sub CPU 102 ends the CZ counter process. To do.

<Processing during CZ>
FIG. 86 and FIG. 87 are flowcharts showing the in-CZ process executed in step S453 of the start command reception process shown in FIG.

  First, the sub CPU 102 executes the common processing shown in FIGS. 101 and 102 (S510). Next, the sub CPU 102 determines whether or not the number of CZ lottery games is an initial value (for example, “−1”) (S511).

  If it is determined that the number of CZ lottery games is the initial value (YES), the sub CPU 102 sets 5 as the number of CZ lottery games (S512). Next, the sub CPU 102 clears (invalidates) the CZ hold flag (S513).

  Next, the sub CPU 102 determines whether or not the sub gaming state is CZ3 or CZ4 (S514). If it is determined that the sub gaming state is CZ3 or CZ4 (YES), the sub CPU 102 determines whether or not the number of remaining GG games (hereinafter simply referred to as “number of remaining GG games”) is 0 or more. Is determined (S515).

  If it is determined that the number of remaining GG games is 0 or more (YES), the sub CPU 102 adds 1 to the number of remaining GG games (S516). On the other hand, if it is determined that the number of remaining GG games is not 0 or more (NO), the sub CPU 102 sets 1 to the number of remaining GG games (S517).

  If it is determined in step S511 that the number of CZ lottery games is not the initial value (NO), if it is determined in step S514 that the sub game state is neither CZ3 or CZ4 (NO), or step S516 or S517 After the processing is completed, the sub CPU 102 determines whether or not the CZ hold flag is valid (S518).

  If it is determined that the CZ hold flag is not valid (NO), the sub CPU 102 determines whether or not the number of CZ lottery games is 0 (S519). Here, when it is determined that the number of CZ lottery games is 0 (YES), the sub CPU 102 ends the process during CZ. On the other hand, when determining that the number of CZ lottery games is not 0 (NO), the sub CPU 102 subtracts 1 from the number of CZ lottery games (S520).

  Next, the sub CPU 102 determines whether or not the sub flag conversion number is 25 (that is, the sub flag conversion combination name is “GOD”) (S521). If it is determined that the subflag conversion number is not 25 (NO), the sub CPU 102 has one of the subflag conversion numbers 22 to 24 (that is, the subflag conversion role name is “right red 7”, “red 7N”). Or “Red 7SP” (hereinafter, also collectively referred to as “Red 7”) (S522).

  Here, when it is determined that the sub flag conversion number is not any of 22 to 24 (NO), the sub CPU 102 refers to the CZ number group lottery table shown in FIG. 41, and displays the sub gaming state (CZ1 to CZ4). CZ number group lottery for determining a number group by lottery with a probability corresponding to any one) and the sub flag lottery number (S523), and the number group as a result of the CZ number group lottery is stored in the sub RAM 103 (S524). , The process during CZ is terminated.

  If it is determined in step S521 that the sub flag conversion number is 25 (YES), the sub CPU 102 sets GG to the next gaming state (S525). If it is determined in step S522 that the sub flag conversion number is any of 22 to 24 (YES), or after executing the process of step S525, the sub CPU 102 clears the number of CZ lottery games to an initial value ( S526), the CZ hold flag is cleared (S527), and the process during CZ is terminated.

  If it is determined in step S518 that the CZ hold flag is valid (YES), the sub CPU 102 determines whether or not the sub flag conversion number is 25 (that is, the sub flag conversion combination name is “GOD”) ( S528).

  If it is determined that the subflag conversion number is not 25 (NO), the sub CPU 102 selects one of the subflag conversion numbers 22 to 24 (that is, the subflag conversion role name is “red 7”, “red 7N” or It is determined whether or not it is “Red 7SP” (S529).

  Here, if it is determined that the sub flag conversion number is not any of 22 to 24 (NO), the sub CPU 102 stores the post-CZHOLD GG winning rate lottery table shown in FIGS. 48 and 49 in the sub RAM 103. GG winning rate lottery table after CZHOLD is determined by referring to the post-CZHOLD GG winning rate lottery table corresponding to the number group, and by determining the GG winning rate by lottery with the probability associated with the sub-flag lottery number (S530), and after CZHOLD A CZGG hold winning rate representing the result of the GG winning rate lottery is set in the sub-RAM 103 (S531).

  Next, the sub CPU 102 refers to the post-CZHOLD post-GG lottery table shown in FIG. 50, and performs post-CZHOLD post-GG lottery that determines the winning of the GG by lottery with the probability associated with the post-CZHOLD post-GG winning rate (S532). . Next, the sub CPU 102 determines whether or not GG or EG is won by GG lottery after CZHOLD (S533).

  Here, if it is determined that neither GG nor EG has been won (NO), the sub CPU 102 ends the processing during CZ, while if it is determined that GG or EG has been won ( YES), the sub CPU 102 determines all the stop events, that is, the types of all the decorative symbols (S534).

  Next, the sub CPU 102 refers to the CZ output group conversion table shown in FIGS. 43 and 44 and executes a CZ output group conversion process for specifying an output group number associated with all stop events. (S535).

  Next, the sub CPU 102 determines the number of added GG counters to be added to the value of the GG counter according to the output group number (S536). In the present embodiment, the sub CPU 102 determines that the addition GG counter number is 5 when the output group number is 9 or 10, and when the output group number is other than 9 or 10 and wins GG. The addition GG counter number is determined to be 1.

  Next, the sub CPU 102 adds the number of added GG counters to the value of the GG counter (S537). Next, the sub CPU 102 performs a GG winning allocation lottery for distributing the GG continuation rate (S538).

  In the GG winning allocation lottery, the sub CPU 102 refers to the GG winning allocation table shown in FIG. 45, identifies the allocation number associated with the gaming state and the sub flag lottery number, and performs the GG winning allocation shown in FIG. With reference to the distribution lottery table, the GG continuation rate is determined by lottery with the probability associated with the distribution number.

  Next, the sub CPU 102 stocks the GG continuation rate determined by the GG winning allocation lottery in the sub RAM 103 (S539). Next, the sub CPU 102 determines whether or not the EG has been won (S540). Specifically, if the outcome group number is 11, the sub CPU 102 determines that the EG has been won, and if the outcome group number is other than 11, the sub CPU 102 determines that the EG has not been won.

  If the sub CPU 102 determines that the EG has been won (YES), the sub CPU 102 sets the EG to the CZ hold GG winning flag (S541), and ends the CZ processing. On the other hand, if it is determined that the EG has not been won (NO), the sub CPU 102 sets GG to the CZ hold GG winning flag (S542), and ends the CZ processing.

  If it is determined in step S528 that the sub flag conversion number is 25 (YES), the sub CPU 102 sets GG to the next gaming state (S543). When it is determined in step S528 that the sub flag conversion number is any of 22 to 24 (YES), or after executing the process of step S543, the sub CPU 102 clears the number of CZ lottery games (S544). Then, the CZ hold flag is cleared (S545), and the CZ processing is terminated.

<Reel stop command reception processing>
FIG. 88 is a flowchart showing the reel stop command reception process executed in step S439 of the effect content determination process shown in FIG.

  First, the sub CPU 102 determines whether or not the sub gaming state is any of CZ1 to CZ4 (S560). If it is determined that the sub game state is not any of CZ1 to CZ4 (NO), the sub CPU 102 ends the reel stop command reception process.

  On the other hand, when it is determined that the sub gaming state is any one of CZ1 to CZ4 (YES), the sub CPU 102 determines whether or not the reel stop command represents the stop of the first stop reel or the second stop reel. Judgment is made (S561).

  Here, if it is determined that the reel stop command indicates the stop of the first stop reel or the second stop reel (YES), the sub CPU 102 executes the 1 stop and 2 stop processing shown in FIG. S562), the reel stop command reception process is terminated.

  On the other hand, when it is determined that the reel stop command does not indicate the stop of the first stop reel or the second stop reel (NO), that is, when it is determined that the reel stop command indicates the stop of the third stop reel. The sub CPU 102 executes the three stop processing shown in FIGS. 90 to 92 (S563), and ends the reel stop command reception processing.

<1 stop, 2 stop processing>
FIG. 89 is a flowchart showing the 1-stop and 2-stop processing executed in step S561 of the reel stop command reception processing shown in FIG.

  First, the sub CPU 102 determines whether or not the gaming state controlled by the main CPU 93 is a BB carryover state (S570). Here, when it is determined that the gaming state controlled by the main CPU 93 is not the BB carryover state (NO), the sub CPU 102 ends the process for one stop and two stops.

  On the other hand, when it is determined that the gaming state controlled by the main CPU 93 is the BB carryover state (YES), the sub CPU 102 determines whether the sub flag conversion number is 25 (that is, the sub flag conversion combination name is “GOD”). Is determined (S571).

  Here, if it is determined that the subflag conversion number is 25 (YES), the sub CPU 102 ends the 1 stop and 2 stop processing. On the other hand, if it is determined that the subflag conversion number is not 25 (NO), the subflag conversion number is any of 22 to 24 (that is, the subflag conversion role name is “right red 7”, “red 7N”, or “red 7SP”. ) Is determined (S572).

  Here, when it is determined that the sub flag conversion number is any of 22 to 24 (YES), the sub CPU 102 ends the 1 stop and 2 stop processing. On the other hand, when it is determined that the sub flag conversion number is not any of 22 to 24 (NO), the sub CPU 102 determines whether or not the CZ hold flag is valid (S573).

  Here, when it is determined that the CZ hold flag is valid (YES), the sub CPU 102 ends the process for one stop and two stops. On the other hand, if it is determined that the CZ hold flag is not valid (NO), the sub CPU 102 determines that the first stop mirror, the second stop mirror and the second stop mirror included in the CZ output group lottery table shown in FIG. With reference to the corresponding table among the tables with the stop mirror, CZ outcome group lottery is performed in which the type of decorative symbol is determined by lottery with the probability associated with the number group stored in the sub-RAM 103 during the CZ processing ( S574).

  Next, when the reel stop command indicates the stop of the first stop reel, the sub CPU 102 determines the left stop output, which is the left decorative symbol, as the result of the CZ output group lottery, and the reel stop command is In the case of representing the stop of the two-stop reel, the medium stop output which is the decorative pattern in the center is determined as the result of the CZ output group lottery (S575), and the process for one stop and two stops is ended.

  In step S575, as shown in FIG. 112, when a decorative symbol other than “mirror” is determined as the middle stop event, and “mirror” is determined as the left stop event, the sub CPU 102 Change the left stop appearance to the same type of decorative pattern as the middle stop appearance.

<Processing at 3 stops>
90 to 92 are flowcharts showing the 3-stop process executed in step S562 of the reel stop command reception process shown in FIG.

  First, the sub CPU 102 determines whether or not the gaming state controlled by the main CPU 93 is a BB carryover state (S580). Here, when it is determined that the gaming state controlled by the main CPU 93 is not the BB carryover state (NO), the sub CPU 102 ends the three-stop process.

  On the other hand, when it is determined that the gaming state controlled by the main CPU 93 is the BB carryover state (YES), the sub CPU 102 determines whether the sub flag conversion number is 25 (that is, the sub flag conversion combination name is “GOD”). Is determined (S581).

  Here, if it is determined that the sub flag conversion number is 25 (YES), the sub CPU 102 ends the three-stop process. On the other hand, if it is determined that the subflag conversion number is not 25 (NO), the subflag conversion number is any of 22 to 24 (that is, the subflag conversion role name is “right red 7”, “red 7N”, or “red 7SP”. ) Is determined (S582).

  Here, when it is determined that the sub flag conversion number is any of 22 to 24 (YES), the sub CPU 102 ends the three-stop process. On the other hand, when it is determined that the sub flag conversion number is not any of 22 to 24 (NO), the sub CPU 102 determines whether or not the CZ hold flag is valid (S583).

  If it is determined that the CZ hold flag is not valid (NO), the sub CPU 102 refers to the third stop table included in the CZ output group lottery table shown in FIG. In step S584, CZ outcome group lottery is performed in which the type of decorative symbol is determined by lottery with the probability associated with the number group stored in the sub RAM 103.

  Next, based on the result of the CZ event group lottery, the sub CPU 102 determines the right stop event that is the right decorative symbol (S585). In step S585, as shown in FIG. 113, when “right” is determined as the left stop output and the middle stop output when the right stop output is determined, the sub CPU 102 Change the stop pattern and middle stop pattern to the same type of decorative pattern as the right stop pattern.

  Next, the sub CPU 102 refers to the CZ output group conversion table shown in FIGS. 43 and 44 and specifies the type of the left, middle and right decorative symbols, that is, the output group number corresponding to the display output. The CZ output group conversion process is executed (S586).

  Next, the sub CPU 102 determines whether the outcome group number is any one of 1 to 6, that is, whether the outcome group has won the hold (S587). Here, if it is determined that the hold is won (YES), the sub CPU 102 refers to the CZHOLD lottery table shown in FIG. 47 and determines whether there is a hold with the probability associated with the output group number. CZHOLD lottery for lottery is performed (S588).

  Next, the sub CPU 102 determines whether or not the result of the CZHOLD lottery is “hold” (S589). Here, if it is determined that the result of CZHOLD lottery is “hold” (YES), the sub CPU 102 sets a CZ hold flag (S590) and ends the three-stop process.

  If it is determined in step S587 that the hold has not been won (NO), the sub CPU 102 determines whether the outcome group number is 7 to 11, that is, whether or not the GG has been won (S591). .

  If it is determined that GG is won (YES), the sub CPU 102 determines the number of added GG counters to be added to the value of the GG counter according to the output group number (S592). In the present embodiment, the sub CPU 102 determines the addition GG counter number to be 5 when the output group number is 9 or 10, and adds GG when the output group number is 7, 8 or 11. The number of counters is determined as 1.

  Next, the sub CPU 102 adds the number of added GG counters to the value of the GG counter (S593). Next, the sub CPU 102 performs a GG winning allocation lottery for distributing the GG continuation rate (S594).

  Next, the sub CPU 102 stocks the GG continuation rate determined by the GG winning allocation lottery in the sub RAM 103 (S595). Next, the sub CPU 102 determines whether or not the outcome group number is 7, that is, whether or not the outcome group is a GG winning reach (S596).

  Here, if it is determined that the GG winning reach is (YES), the sub CPU 102 sets a CZ reach eye flag (S597). On the other hand, when it is determined that it is not the GG winning reach (NO), 0 is set to the number of CZ lottery games (S598).

  If it is determined in step S583 that the CZ hold flag is valid (YES), the sub CPU 102 clears the CZ hold flag (S599) and determines whether or not the CZ hold GG winning flag is EG. (S600).

  If it is determined that the CZ hold GG winning flag is not EG (NO), the sub CPU 102 determines whether or not the CZ hold GG winning flag is GG (S601).

  If it is determined in step S600 that the CZ hold GG winning flag is EG (YES), or if it is determined in step S601 that the CZ hold GG winning flag is GG (YES), the sub CPU 102 The number of CZ lottery games is set to 0 (S602).

  If it is determined in step S589 that the CZ hold lottery result indicates that there is no hold (NO), or if it is determined in step S591 that GG has not been won (NO), the CZ hold GG winning flag is set to GG in step S601. If it is determined that it is not (NO), and after executing the processing of step S597, S598 or S602, the sub CPU 102 determines whether or not the number of CZ lottery games is 0 (S603).

  Here, when it is determined that the number of CZ lottery games is not 0 (NO), the sub CPU 102 ends the three-stop process. On the other hand, when it is determined that the number of CZ lottery games is 0 (YES), the sub CPU 102 determines whether or not the CZ hold GG winning flag is EG (S604).

  If it is determined that the CZ hold GG winning flag is not EG (NO), the sub CPU 102 determines whether or not the outcome group number is 11, that is, whether or not the EG is won. (S605).

  If it is determined in step S604 that the CZ hold GG winning flag is EG (YES), or if it is determined in step S605 that EG has been won (YES), the sub CPU 102 determines the next gaming state as EG. (S606) and the 3 stop process is terminated.

  If it is determined in step S605 that the EG has not been won (NO), the sub CPU 102 determines whether or not the sub gaming state is CZ3 or CZ4 (S607). Here, if it is determined that the sub gaming state is CZ3 or CZ4 (YES), the sub CPU 102 sets the next gaming state to GG (S608), and ends the three-stop process.

  On the other hand, when it is determined that the sub gaming state is neither CZ3 nor CZ4 (NO), the sub CPU 102 determines whether or not the value of the GG counter is 1 or more (S609).

  If it is determined that the value of the GG counter is not 1 or more (NO), the sub CPU 102 determines whether or not the number of CZ information stock is 1 or more (S610). Here, if it is determined that the number of CZ information stock is 1 or more (YES), the sub CPU 102 performs a normal CZ precursor counter lottery (S611), and the normal CZ precursor counter lottery result is normal. It is set in the CZ book precursor counter (S612).

  In step S610, when it is determined that the number of CZ information stock is not 1 or more (NO), or after executing the process of step S612, the sub CPU 102 sets the next gaming state to normal (S613) and stops three times. End time processing.

  If it is determined in step S609 that the value of the GG counter is 1 or more (YES), the sub CPU 102 determines whether or not the CZ reach flag is valid (S614).

  If it is determined that the CZ reach eye flag is not valid (NO), the sub CPU 102 determines whether or not the output group number is any of 8 to 11, that is, the output group is a GG winning reach. It is determined whether or not the GG winning eye is excluded (S615).

  If it is determined that the outcome group is not a GG winning except for the GG winning reach (NO), the sub CPU 102 performs a GG preliminary game number lottery that determines the number of GG preliminary games by lottery (S616). ). In the GG prewar game number lottery, for example, the sub CPU 102 randomly determines one value from a range of 1 to 32.

  Next, the sub CPU 102 sets the result of the GG precursor game number lottery to the GG precursor game number (S617). Next, the sub CPU 102 sets the next gaming state to normal (S618), and ends the three-stop process.

  If it is determined in step S614 that the CZ reach eye flag is valid (YES), or if it is determined in step S615 that the outcome group is a GG win except for the GG winning reach eye (YES), The sub CPU 102 sets the number of GG previous warning games to 0 (S619). Next, the sub CPU 102 sets the next gaming state to GG (S620) and ends the three-stop process.

<In-EG processing>
93 to 95 are flowcharts showing the in-EG process executed in step S455 of the start command reception process shown in FIG.

  First, the sub CPU 102 determines whether or not the number of EG games is an initial value (S640). If it is determined that the number of EG games is an initial value (YES), the sub CPU 102 determines whether or not the number of GG games is an initial value (S641).

  If it is determined that the number of GG games is the initial value (YES), the sub CPU 102 sets the number of GG games to 100 (S642), and subtracts 1 from the value of the GG counter (S643).

  On the other hand, when it is determined that the number of GG games is not the initial value (NO), or after executing the process of step S643, the sub CPU 102 refers to the PEG promotion lottery table shown in FIG. PEG promotion lottery is performed to determine whether or not the sub gaming state is promoted from EG to PEG with the probability associated with (S644).

  Next, the sub CPU 102 determines whether or not it is determined to promote the sub gaming state from EG to PEG based on the result of the PEG promotion lottery, that is, whether or not the PEG is won (S645).

  If it is determined that PEG is won (YES), the sub gaming state is set to PEG (S646), and the next gaming state is also set to PEG (S647). Next, the sub CPU 102 initializes the number of PEG games (S648), executes the in-PEG process shown in FIGS. 98 and 99 (S649), and ends the in-EG process.

  If it is determined in step S645 that the PEG has not been won (NO), the sub CPU 102 sets the number of EG games to 16 (S650). If it is determined in step S640 that the number of EG games is not the initial value (NO), or after the process of step S650 is completed, the sub CPU 102 has one of the sub flag conversion numbers 19 to 25 (that is, the sub flag conversion role name). Is “right red 7F”, “red 7F1”, “red 7F2”, “right red 7”, “red 7N”, “red 7SP” or “GOD”) (S651).

  If it is determined that the sub flag conversion number is any one of 19 to 25 (YES), the sub CPU 102 clears the EG relief flag (S652). When it is determined in step S651 that the sub flag conversion number is not any of 19 to 25 (NO), or after executing the process of step S652, the sub CPU 102 subtracts 1 from the number of EG games (S653). .

  Next, the sub CPU 102 executes the common processing shown in FIGS. 101 and 102 (S654). Next, the sub CPU 102 refers to the rewind lottery table in the EG in the rewind lottery table shown in FIG. 51 and performs rewinding to EG or PEG with the probability associated with the sub flag lottery number. A rewind lottery is performed to determine whether or not by lottery (S655).

  Next, the sub CPU 102 determines whether or not the rewind lottery has been won (S656). If it is determined that the rewind lottery has not been won (NO), the sub CPU 102 refers to the SEG added game number lottery table shown in FIG. 56, and has a probability associated with the sub flag conversion number. The number of games to be added to SEG is determined by lottery, and SEG addition game number lottery is performed (S657).

  Next, the sub CPU 102 determines whether or not an immediate notification of the number of added games is won based on the result of the SEG added game number lottery (S658). If it is determined that the immediate notification of the added game number has not been won (NO), the sub CPU 102 determines whether or not the SEG added game number stock has been won based on the result of the SEG added game number lottery. (S659).

  Here, if it is determined that the SEG addition game number stock has been won (YES), the sub CPU 102 adds the winning stock game number to the SEG stock game number (S660).

  If it is determined in step S659 that the SEG addition game number stock has not been won (NO), or after executing the process of step S660, the sub CPU 102 determines whether or not the number of EG games is zero. (S661).

  Here, if it is determined that the number of EG games is not 0 (NO), the sub CPU 102 ends the EG processing. On the other hand, when it is determined that the number of EG games is 0 (YES), the sub CPU 102 determines whether or not the number of SEG stock games is 1 or more (S662).

  If it is determined that the number of SEG stock games is not 1 or more (NO), the sub CPU 102 initializes the number of EG games (S663) and sets the next game state to GG (S664).

  Next, the sub CPU 102 determines whether or not the EG relief flag is valid (S665). Here, if it is determined that the EG repair flag is valid (YES), the sub CPU 102 determines the GG continuation rate with the probability indicated in the EG remedy GG continuation rate distribution lottery table shown in FIG. The GG continuation rate distribution lottery determined during EG determined by the above (S666), and the GG continuation rate determined by the EG continuation rate distribution lottery during EG is stocked in the sub-RAM 103 (S667).

  If it is determined in step S665 that the EG relief flag is not valid (NO), or after executing the process of step S667, the sub CPU 102 determines whether or not the number of GG games is one or more (S668). .

  Here, when it is determined that the number of GG games is 1 or more (YES), the sub CPU 102 ends the EG processing. On the other hand, if it is determined that the number of GG games is not 1 or more (NO), the sub CPU 102 subtracts 1 from the value of the GG counter (S669), and ends the EG processing.

  If it is determined in step S658 that the SEG addition game number is immediately announced (YES), or if it is determined in step S662 that the SEG stock game number is 1 or more (YES), the sub CPU 102 The SEG initial game number obtained by adding the number of games won for immediate notification and the number of SEG stock games is stored in the sub-RAM 103 (S670).

  Next, the sub CPU 102 initializes the number of SEG stock games (S671), initializes the number of SEG games (S672), sets the next game state to SEG (S673), and ends the processing during EG.

  If it is determined in step S656 that the rewind lottery has been won (YES), the sub CPU 102 initializes the number of SEG stock games (S674). Next, the sub CPU 102 determines whether or not the sub flag conversion number is any of 23 to 25 (that is, the sub flag conversion combination name is “red 7N”, “red 7SP”, or “GOD”) (S675).

  If it is determined that the sub flag conversion number is not any of 23 to 25 (NO), the sub CPU 102 adds 1 to the value of the GG counter (S676). Next, the sub CPU 102 performs a lottery lottery for rewinding to distribute the GG continuation rate added by winning the rewind lottery (S677).

  In the rewinding win allocation lottery, the sub CPU 102 refers to the rewinding win allocation table shown in FIG. 52, specifies the sub gaming state and the allocation number associated with the number of remaining games in the sub gaming state, The GG continuation rate is determined by lottery with reference to the lottery table at the time of rewinding win shown in FIG. 53 with the probability associated with the allocation number.

  Next, the sub CPU 102 stocks the GG continuation rate determined in the rewinding lottery in the sub RAM 103 (S678). If it is determined in step S675 that the sub flag conversion number is any of 23 to 25 (YES), or after executing the process of step S678, the sub CPU 102 initializes the number of EG games (S679).

  Next, the sub CPU 102 determines whether or not the PEG is won by the rewind lottery in step S655 (S680). If it is determined that the PEG has not been won (NO), the sub CPU 102 ends the EG processing.

  On the other hand, if it is determined that PEG is won (YES), the sub CPU 102 initializes the number of PEG games (S681), sets the next game state to PEG (S682), and ends the EG processing.

<Processing during SEG>
96 and 97 are flowcharts showing the SEG in-process executed in step S457 of the start command reception process shown in FIG.

  First, the sub CPU 102 determines whether or not the number of SEG games is an initial value (S700). If it is determined that the SEG game number is the initial value (YES), the sub CPU 102 sets the SEG initial game number stored in the sub RAM 103 as the SEG game number (S701).

  If it is determined in step S700 that the number of SEG games is not the initial value (NO), or after executing the process of step S701, the sub CPU 102 clears the EG relief flag (S702).

  Next, the sub CPU 102 subtracts 1 from the number of SEG games (S703), and executes the common processing shown in FIGS. 101 and 102 (S704). Next, the sub CPU 102 refers to the rewind lottery table in the SEG in the rewind lottery table shown in FIG. 51, and performs rewind to EG or PEG with the probability associated with the sub flag lottery number. A rewind lottery is performed to determine whether or not by lottery (S705).

  Next, the sub CPU 102 determines whether or not the rewind lottery has been won (S706). If it is determined that the rewind lottery has not been won (NO), the sub CPU 102 determines whether or not the number of SEG games is 0 (S707).

  If it is determined that the number of SEG games is not 0 (NO), the sub CPU 102 ends the SEG processing. On the other hand, if it is determined that the number of SEG games is 0 (YES), the sub CPU 102 initializes the number of SEG games (S708).

  Next, the sub CPU 102 determines whether or not the number of EG games is 0 (S709). Here, if it is determined that the number of EG games is not 0 (NO), the sub CPU 102 sets the next game state to EG (S710), and ends the SEG processing.

  On the other hand, if it is determined that the number of EG games is 0 (YES), the sub CPU 102 initializes the number of EG games (S711) and sets the next game state to GG (S712). Next, the sub CPU 102 determines whether or not the number of GG games is 1 or more (S713).

  Here, if it is determined that the number of GG games is not 1 or more (NO), the sub CPU 102 subtracts 1 from the value of the GG counter (S714), and ends the SEG processing. On the other hand, if it is determined that the number of GG games is 1 or more (YES), the sub CPU 102 ends the SEG processing.

  If it is determined in step S706 that the rewind lottery has been won (YES), the sub CPU 102 initializes the number of SEG stock games (S715). Next, the sub CPU 102 determines whether or not the sub flag conversion number is any of 23 to 25 (that is, the sub flag conversion combination name is “red 7N”, “red 7SP”, or “GOD”) (S716).

  If it is determined that the sub flag conversion number is not any of 23 to 25 (NO), the sub CPU 102 adds 1 to the value of the GG counter (S717). Next, the sub CPU 102 performs a lottery lottery for rewinding to distribute the GG continuation rate added by winning the lottery for rewinding (S718).

  Next, the sub CPU 102 stocks the GG continuation rate determined by the lottery lottery for rewinding in the sub RAM 103 (S719).

  If it is determined in step S716 that the sub flag conversion number is any of 23 to 25 (YES), or after executing the process of step S719, the sub CPU 102 initializes the number of EG games (S720), and SEG The number of games is initialized (S721).

  Next, the sub CPU 102 determines whether or not the PEG is won in the rewind lottery in step S706 (S722). If it is determined that the PEG has not been won (NO), the sub CPU 102 sets the next gaming state to EG (S723) and ends the SEG processing.

  On the other hand, if it is determined that PEG is won (YES), the sub CPU 102 initializes the number of PEG games (S724), sets the next game state to PEG (S725), and ends the SEG processing.

<In-PEG processing>
FIGS. 98 and 99 are flowcharts showing the in-PEG processing executed in step S459 of the start command reception processing shown in FIG. 82 and in step S649 of the in-EG processing shown in FIGS.

  First, the sub CPU 102 determines whether or not the number of PEG games is an initial value (S740). If it is determined that the number of PEG games is the initial value (YES), the sub CPU 102 determines whether or not the number of GG games is the initial value (S741).

  If it is determined that the number of GG games is the initial value (YES), the sub CPU 102 sets 100 to the number of GG games (S742), and subtracts 1 from the value of the GG counter (S743).

  When it is determined in step S741 that the number of GG games is not the initial value (NO), or after executing the process of step S743, the sub CPU 102 sets 16 as the number of PEG games (S744).

  If it is determined in step S740 that the number of PEG games is not the initial value (NO), or after executing the process of step S744, the sub CPU 102 clears the EG relief flag (S745).

  Next, the sub CPU 102 subtracts 1 from the number of PEG games (S746), and executes the common processing shown in FIGS. 101 and 102 (S747). Next, the sub CPU 102 refers to the rewind lottery table in the PEG in the rewind lottery table shown in FIG. 51, and performs rewinding to EG or PEG with the probability associated with the sub flag lottery number. A rewind lottery is performed to determine whether or not by lottery (S748).

  Next, the sub CPU 102 determines whether or not the rewind lottery has been won (S749). If it is determined that the rewind lottery has not been won (NO), the sub CPU 102 determines whether or not the number of PEG games is 0 (S750).

  If it is determined that the number of PEG games is not 0 (NO), the sub CPU 102 ends the in-PEG process. On the other hand, if it is determined that the number of PEG games is 0 (YES), the sub CPU 102 initializes the number of PEG games (S751).

  Next, the sub CPU 102 sets the next gaming state to GG (S752), and determines whether or not the number of GG games is 1 or more (S753). Here, if it is determined that the number of GG games is not 1 or more (NO), the sub CPU 102 subtracts 1 from the value of the GG counter (S754), and ends the in-PEG processing. On the other hand, if it is determined that the number of GG games is 1 or more (YES), the sub CPU 102 ends the in-PEG processing.

  If it is determined in step S749 that the rewind lottery has been won (YES), the sub CPU 102 initializes the number of SEG stock games (S755). Next, the sub CPU 102 determines whether or not the sub flag conversion number is any of 23 to 25 (that is, the sub flag conversion combination name is “red 7N”, “red 7SP”, or “GOD”) (S756).

  If it is determined that the sub flag conversion number is not any of 23 to 25 (NO), the sub CPU 102 adds 1 to the value of the GG counter (S757). Next, the sub CPU 102 performs rewinding lottery lottery for distributing the GG continuation rate added by winning the rewind lottery (S758).

  Next, the sub CPU 102 stocks the GG continuation rate determined by the lottery lottery for rewinding in the sub RAM 103 (S759).

  If it is determined in step S756 that the sub flag conversion number is any of 23 to 25 (YES), or after executing the process of step S759, the sub CPU 102 initializes the number of PEG games (S760).

  Next, the sub CPU 102 determines whether or not the EG is won by the rewind lottery in step S756 (S761). If it is determined that the EG has not been won (NO), the sub CPU 102 ends the in-PEG processing.

  On the other hand, if it is determined that EG has been won (YES), the sub CPU 102 initializes the number of EG games (S762), sets the next game state to EG (S763), and ends the in-PEG process.

<In-GG processing>
FIG. 100 is a flowchart showing the in-GG process executed in step S461 of the start command reception process shown in FIG.

  First, the sub CPU 102 determines whether or not the number of GG games is an initial value (S780). If it is determined that the number of GG games is the initial value (YES), the sub CPU 102 sets the number of GG games to 100 (S781).

  When it is determined in step S780 that the number of GG games is not the initial value (NO), or after executing the process of step S781, the sub CPU 102 executes the common process shown in FIGS. 101 and 102 (S782). 1 is subtracted from the number of GG games (S783).

  Next, the sub CPU 102 determines whether or not the number of GG games is 0 (S784). Here, if it is determined that the number of GG games is not 0 (NO), the sub CPU 102 ends the GG in-process. On the other hand, if it is determined that the number of GG games is 0 (YES), the sub CPU 102 determines whether or not the number of CZ pre-game games in the GG is 0 or more (S785).

  Here, if it is determined that the number of CZ precursor games in GG is 0 or more (YES), the sub CPU 102 ends the GG processing. On the other hand, if it is determined that the number of CZ precursor games in the GG is not 0 or more (NO), the sub CPU 102 has any of the sub flag conversion numbers 22 to 24 (that is, the sub flag conversion role name is “right red 7”, It is determined whether or not it is “Red 7N” or “Red 7SP” (S786).

  Here, if it is determined that the sub flag conversion number is any of 22 to 24 (YES), the sub CPU 102 adds 1 to the number of GG games (S787), and ends the GG processing.

  On the other hand, if it is determined that the sub flag conversion number is not any of 22 to 24 (NO), the sub CPU 102 initializes the number of GG games (S788) and subtracts 1 from the value of the GG counter (S789).

  Next, the sub CPU 102 determines whether or not the value of the GG counter is 0 or more (S790). Here, if it is determined that the value of the GG counter is not equal to or greater than 0 (NO), the sub CPU 102 performs a GG prelude game number lottery to determine the number of GG predecessor games by lottery (S791). The result of the game number lottery is set to the number of GG precursor games (S792).

  If it is determined in step S790 that the value of the GG counter is 0 or more (YES), or after executing the process of step S792, the sub CPU 102 sets the next gaming state to normal (S793). The GG in-process is terminated.

<Common processing>
101 and FIG. 102 show step S462 of the start command reception process shown in FIG. 82, step S510 of the CZ intermediate process shown in FIGS. 86 and 87, and step S654 of the EG intermediate process shown in FIGS. 96 and 97, common processing executed in step S704 of the SEG in-process shown in FIG. 96, step S747 of the PEG in-process shown in FIGS. 98 and 99, and step S782 of the GG in-process shown in FIG. It is a flowchart which shows.

  First, the sub CPU 102 executes history information generation processing shown in FIGS. 103 to 106 (S800). Next, the sub CPU 102 refers to the history lottery tables shown in FIG. 57 and FIG. 58, and draws GG, CZ1 to CZ4 and GG + CZ1 with a probability according to the result of the sub gaming state and the history information generation process. (S801).

  Next, the sub CPU 102 determines whether or not a GG is won by history lottery (S802). If it is determined that the GG is won by the history lottery (YES), the sub CPU 102 adds 1 to the value of the GG counter (S803).

  Next, the sub CPU 102 performs a GG winning allocation lottery for distributing the GG continuation rate added by winning the history lottery (S804). Next, the sub CPU 102 stocks the GG continuation rate determined by the GG winning allocation lottery in the sub RAM 103 (S805).

  Next, the sub CPU 102 determines whether or not a GG book sign is in progress (S807). Here, when it is determined that the GG sign is not in progress (NO), the sub CPU 102 determines whether or not the sub gaming state is normal (S808).

  Here, if it is determined that the sub gaming state is normal (YES), the sub CPU 102 performs a GG prewar game number lottery that determines the GG prewar game number by lottery (S809). Next, the sub-CPU 102 sets the result of the GG precursor game number lottery to the GG precursor game number (S810), and initializes the normal CZ precursor signal counter (S811).

  If it is determined in step S802 that the GG has not been won by history lottery (NO), or if it is determined in step S807 that the GG is a precursor (YES), it is determined in step S808 that the sub gaming state is not normal. If it is (NO), or after executing the process of step S811, the sub CPU 102 determines whether or not CZ1 has been won in the history lottery (S812).

  If it is determined that CZ1 is won by history lottery (YES), the sub CPU 102 sets CZ1 in the CZ information stock (S813). On the other hand, if it is determined that CZ1 has not been won by history lottery (NO), the sub CPU 102 determines whether or not CZ2 has been won by history lottery (S814). If it is determined that CZ2 is won in the history lottery (YES), the sub CPU 102 sets CZ2 in the CZ information stock (S815).

  After the process of step S813 or S815 is completed, the sub CPU 102 determines whether or not a GG precursor is in progress (S816). Here, if it is determined that the sign of GG is in progress (YES), the sub CPU 102 ends the common process.

  On the other hand, if it is determined that the GG sign is not present (NO), the sub CPU 102 determines whether or not the CZ sign is present (S817). Here, if it is determined that CZ number is in the foreground (YES), the sub CPU 102 ends the common processing.

  On the other hand, if it is determined that the GG sign is not present (NO), the sub CPU 102 determines whether or not the CZ sign is present (S817). Here, if it is determined that CZ number is in the foreground (YES), the sub CPU 102 ends the common processing.

  On the other hand, if it is determined that the previous CZ sign is not present (NO), the sub CPU 102 determines whether or not the sub gaming state is normal (S818). If it is determined that the sub gaming state is not normal (NO), the sub CPU 102 ends the common process.

  On the other hand, if it is determined that the sub gaming state is normal (YES), the sub CPU 102 performs a normal medium CZ precursor counter lottery (S819), and the result of the normal medium CZ precursor counter lottery is obtained as a normal medium CZ precursor counter. (S820), and the common process is terminated.

  If it is determined in step S814 that CZ2 has not been won by history lottery (NO), the sub CPU 102 determines whether or not CZ3 has been won by history lottery (S821).

  When it is determined that the history lottery has won CZ3 (YES), the sub CPU 102 sets CZ3 in the CZ information stock (S822). On the other hand, if it is determined that CZ3 is not won by history lottery (NO), the sub CPU 102 determines whether CZ4 is won by history lottery (S823).

  Here, if it is determined that CZ4 has been won in the history lottery (YES), the sub CPU 102 sets CZ4 in the CZ information stock (S824). On the other hand, if it is determined in the history lottery that CZ4 has not been won (NO), the sub CPU 102 ends the common processing.

  After executing the processing of step S822 or S824, the sub CPU 102 determines whether or not the sub flag conversion number is 25 (that is, the sub flag conversion combination name is “GOD”) (S825). If it is determined that the sub flag conversion number is 25, the sub CPU 102 ends the common process.

  On the other hand, if it is determined that the sub flag conversion number is not 25 (NO), the sub CPU 102 determines whether or not a CZ precursor is being performed (S826). Here, if it is determined that CZ number is in the foreground (YES), the sub CPU 102 ends the common processing.

  On the other hand, if it is determined that the previous CZ sign is not present (NO), the sub CPU 102 determines whether or not the sub gaming state is GG (S827). If it is determined that the sub game state is not GG (NO), the sub CPU 102 ends the common process.

  On the other hand, if it is determined that the sub gaming state is GG (YES), the sub CPU 102 performs the GG CZ precursor game number lottery (S828), and the GG CZ precursor game number lottery results are CZ in GG. The number of precursor games is set (S829), and the common process is terminated.

<History information generation process>
103 to 106 are flowcharts showing the history information generation process executed in step S800 of the common process shown in FIGS. 101 and 102.

  First, the sub CPU 102 sets a loss in the history information (S840). In the present embodiment, the history information stores a result of 5 unit games as a history. That is, when a history is set in the history information, the history before the 5 unit game is deleted, and the set history is newly stored in the history information.

  Next, the sub CPU 102 has a sub flag conversion number of 10 to 12 or 14 (that is, the sub flag conversion combination name is “normal lip”, “left normal lip”, “medium normal lip”, or “C lip”). Whether or not (S841).

  If it is determined that the sub flag conversion number is not any of 10 to 12 or 14 (NO), the sub CPU 102 sets the value of the history blue consecutive counter to 0 (S842). On the other hand, if it is determined that the sub flag conversion number is either 10-12 or 14 (YES), the sub CPU 102 sets “history blue” in the history information (S843).

  After executing the processing of S843, the sub CPU 102 determines whether or not the value of the history Serenso counter is 5 or more (S844). Here, if it is determined that the value of the history Seirenso counter is not 5 or more (NO), the sub CPU 102 adds 1 to the value of the history Seirenso counter (S845).

  In step S844, when it is determined that the value of the history Serenso counter is 5 or more (YES), or after executing the process of step S842 or S845, the sub CPU 102 has any of the sub flag conversion numbers 6-9. (That is, whether the sub-flag conversion combination name is “213L bell”, “231L bell”, “312L bell” or “321L bell”) (S846).

  Here, if it is determined that the sub flag conversion number is not any of 6 to 9 (NO), the sub CPU 102 sets the value of the history white renso counter to 0 (S847). On the other hand, when it is determined that the sub flag conversion number is any of 6 to 9 (YES), the sub CPU 102 sets “history white” in the history information (S848).

  After executing the processing of S848, the sub CPU 102 determines whether or not the value of the history white renzi counter is 5 or more (S849). If it is determined that the value of the history white renja counter is not 5 or more (NO), the sub CPU 102 adds 1 to the value of the history white renso counter (S850).

  In step S849, when it is determined that the value of the history white renso counter is 5 or more (YES), or after executing the processing of step S847 or S850, the sub CPU 102 has sub flag conversion numbers of 2 to 5, 13 Or any of 15 to 17 (that is, the subflag conversion role names are “213 bell”, “231 bell”, “312 bell”, “321 bell”, “B yellow Lip”, “left CU bell”, “CU bell”) Or “C bell”) (S851).

  Here, if it is determined that the sub flag conversion number is not any of 2 to 5, 13 or 15 to 17 (NO), the sub CPU 102 sets the value of the history yellow Renso counter to 0 (S852). On the other hand, if it is determined that the sub flag conversion number is any of 2 to 5, 13 or 15 to 17 (YES), the sub CPU 102 sets “history yellow” in the history information (S853).

  After executing the processing of S853, the sub CPU 102 determines whether or not the value of the history yellow Renso counter is 5 or more (S854). Here, if it is determined that the value of the history Huang Renzhuang counter is not 5 or more (NO), the sub CPU 102 adds 1 to the value of the history Huang Renzhuang counter (S855).

  In step S854, when it is determined that the value of the history yellow Renso counter is 5 or more (YES), or after executing the process of step S852 or S855, the sub CPU 102 has any of the sub flag conversion numbers 18 to 21. (Ie, the sub-flag conversion combination name is “special combination SP”, “right red 7F”, “red 7F1”, or “red 7F2”) (S856). If it is determined that the sub flag conversion number is any of 18 to 21 (YES), the sub CPU 102 sets “special role” in the history information (S857).

  If it is determined in step S856 that the sub flag conversion number is not any of 18 to 21 (NO), or after executing the process of step S857, the sub CPU 102 has any of the sub flag conversion numbers of 22 to 24 (that is, Then, it is determined whether or not the sub-flag conversion combination name is “Right Red 7”, “Red 7N” or “Red 7SP”) (S858).

  Here, when it is determined that the sub flag conversion number is not any of 22 to 24 (NO), the sub CPU 102 initializes the red 7 consecutive home counter (S859). On the other hand, when it is determined that the sub flag conversion number is any of 22 to 24 (YES), the sub CPU 102 sets “red 7” in the history information (S860).

  After executing the processing of S860, the sub CPU 102 determines whether or not the value of the red 7 consecutive home counter is 5 or more (S861). If it is determined that the value of the red 7 consecutive home counter is not 5 or more (NO), the sub CPU 102 adds 1 to the value of the red 7 consecutive home counter (S862).

  If it is determined in step S861 that the value of the red 7 consecutive house counter is 5 or more (YES), or after executing the process of step S859 or S862, the sub CPU 102 has a sub flag conversion number of 25 (ie, sub flag It is determined whether or not the conversion combination name is “GOD”) (S863).

  If it is determined that the sub flag conversion number is 25 (YES), the sub CPU 102 sets “GOD” in the history information (S864). After executing the process of step S864, the sub CPU 102 determines whether or not “GOD” is set twice or more in the history information (S865).

  Here, if it is determined that “GOD” is set twice or more in the history (YES), the sub CPU 102 sets the history result to 15 (“GOD” is set twice or more within 5G). (S866), the history information generation process is terminated.

  If it is determined in step S863 that the sub flag conversion number is not 25 (NO), or if it is determined in step S865 that “GOD” is not set twice or more in the history (NO), the sub CPU 102 Determines whether the value of the red 7 series counter is 2 or more (S867).

  If it is determined that the value of the red 7 series counter is 2 or more (YES), the sub CPU 102 sets the history result to 14 (“red 7” is 2 or more) (S868), The history information generation process ends. On the other hand, if it is determined that the value of the red 7 series counter is not 2 or more (NO), the sub CPU 102 has one of the sub flag conversion numbers 22 to 24 (that is, the sub flag conversion combination name is “right red 7”, It is determined whether it is “red 7N” or “red 7SP” (S869).

  If it is determined that the sub flag conversion number is any of 22 to 24 (YES), the sub CPU 102 determines whether or not “red 7” is set three times or more in the history ( S870).

  If it is determined that “red 7” is set three times or more in the history (YES), the sub CPU 102 sets the history result to 13 (“red 7” is 3 times or more within 5G). Set (S871), the history information generation process is terminated.

  On the other hand, if it is determined that “red 7” is not set three times or more in the history (NO), the sub CPU 102 determines whether or not “red 7” is set twice or more in the history. (S872).

  Here, when it is determined that “red 7” is set twice or more in the history (YES), the sub CPU 102 sets the history result to 12 (“red 7” is set twice within 5G). (S873), and the history information generation process ends.

  If it is determined in step S869 that the sub flag conversion number is not any of 22 to 24 (NO), or if it is determined in step S872 that “red 7” is not set twice or more in the history (NO), the sub CPU 102 has one of the sub flag conversion numbers 18 to 21 (that is, the sub flag conversion combination name is “special combination SP”, “right red 7F”, “red 7F1” or “red 7F2”, hereinafter simply It is determined whether it is “special role”) (S874).

  Here, if it is determined that the sub flag conversion number is any of 18 to 21 (YES), the sub CPU 102 determines whether or not the “special role” is set five times or more in the history ( S875).

  If it is determined that the “special role” is set five times or more in the history (YES), the sub CPU 102 sets the history result to 11 (the “special role” is 5 times within 5G). (S876), and the history information generation process is terminated.

  On the other hand, if it is determined that the “special role” is not set five times or more in the history (NO), the sub CPU 102 determines whether or not the “special role” is set four times or more in the history. (S877).

  If it is determined that “special role” has been set four times or more in the history (YES), the sub CPU 102 sets the history result to 10 (“special role” within 4G within 4G). (S878), and the history information generation process ends.

  On the other hand, when it is determined that the “special role” is not set four times or more in the history (NO), the sub CPU 102 determines whether or not the “special role” is set three times or more in the history. (S879).

  If it is determined that “special role” has been set three times or more in the history (YES), the sub CPU 102 sets the history result to 9 (“special role” within 3G within 3G). (S880), and the history information generation process is terminated.

  On the other hand, when it is determined that the “special role” is not set three times or more in the history (NO), the sub CPU 102 determines whether or not the “special role” is set twice or more in the history. (S881).

  If it is determined that the “special role” is set twice or more in the history (YES), the sub CPU 102 sets the history result to 8 (the “special role” is 2 times or more within 5G). Set (S882), the history information generation process is terminated.

  When it is determined in step S874 that the sub flag conversion number is not any of 18 to 21 (NO), or when it is determined in step S881 that “special role” is not set twice or more in the history (NO), the sub CPU 102 determines whether or not the value of the history white renso counter is 5 or more (S883).

  Here, when it is determined that the value of the history white renso counter is 5 or more (YES), the sub CPU 102 sets the history result to 7 (historical white 5 consecutive) (S884), and history information generation processing Exit. On the other hand, when it is determined that the value of the history white ranger counter is not 5 or more (NO), the sub CPU 102 determines whether or not the value of the history white ranger counter is 5 or more (S885).

  Here, when it is determined that the value of the history yellow renso counter is 5 or more (YES), the sub CPU 102 sets the history result to 6 (history yellow 5 continuations) (S886), and history information generation processing Exit. On the other hand, when it is determined that the value of the history Huang Renzhuang counter is not 5 or more (NO), the sub CPU 102 determines whether the value of the history Huang Renzhuang counter is 4 or more (S887).

  If it is determined that the value of the history yellow renso counter is 4 or more (YES), the sub CPU 102 sets the history result to 5 (history yellow quadruple) (S888), and history information generation processing Exit. On the other hand, if it is determined that the value of the history Huang Renzhuang counter is not 4 or more (NO), the sub CPU 102 determines whether the value of the history Huang Renzhuang counter is 3 or more (S889).

  Here, if it is determined that the value of the history yellow renso counter is 3 or more (YES), the sub CPU 102 sets the history result to 4 (history yellow triple) (S890), and history information generation processing Exit. On the other hand, if it is determined that the value of the history yellow renso counter is not 3 or more (NO), the sub CPU 102 determines whether or not the value of the history blue renso counter is 5 or more (S891).

  Here, when it is determined that the value of the history Seirenso counter is 5 or more (YES), the sub CPU 102 sets the history result to 3 (History Blue 5 Series) (S892), and history information generation processing Exit. On the other hand, if it is determined that the value of the history Seirenso counter is not 5 or more (NO), the sub CPU 102 determines whether or not the value of the history Seirenso counter is 4 or more (S893).

  Here, when it is determined that the value of the history Seiryoso counter is 4 or more (YES), the sub CPU 102 sets the history result to 2 (history blue 4th) (S894), and history information generation processing Exit. On the other hand, if it is determined that the value of the history Seirenso counter is not 4 or more (NO), the sub CPU 102 determines whether or not the value of the history Seirenso counter is 3 or more (S895).

  Here, when it is determined that the value of the history Seireo counter is 3 or more (YES), the sub CPU 102 sets the history result to 1 (history blue triplet) (S896), and history information generation processing Exit. On the other hand, if it is determined that the value of the history Seiryuso counter is not 3 or more (NO), the sub CPU 102 sets the history result to 0 (none) (S897), and ends the history information generation process.

<Common lottery processing>
FIG. 107 is a flowchart showing the common lottery process executed in step S463 of the start command reception process shown in FIG.

  First, the sub CPU 102 refers to the addition GG number lottery table corresponding to the sub gaming state among the addition GG number lottery tables (not shown) prepared for each sub gaming state, and determines the addition GG number by lottery (S900). . Here, in the addition GG number lottery table, the winning probability of each addition GG number is associated with the sub flag lottery number.

  Next, the sub CPU 102 determines whether or not the added GG number is 0 (S901). If it is determined that the added GG number is 0, the sub CPU 102 ends the common lottery process.

  On the other hand, when determining that the added GG number is not 0, the sub CPU 102 sets or adds the added GG number to the value of the GG counter (S902). That is, when the value of the GG counter is the initial value, the sub CPU 102 sets the number of GGs added to the value of the GG counter. When the value of the GG counter is not the initial value, the sub CPU 102 adds GG to the value of the GG counter. Add a number.

  Next, the sub CPU 102 determines whether or not the sub gaming state is GG, EG, SEG, or PEG (S903). Here, when it is determined that the sub gaming state is any one of GG, EG, SEG, or PEG (YES), the sub CPU 102 ends the common lottery process.

  On the other hand, if it is determined that the sub game state is not GG, EG, SEG or PEG (NO), the sub CPU 102 performs GG winning lottery for distributing the GG continuation rate (S904). Next, the sub CPU 102 stocks the GG continuation rate determined by the GG winning allocation lottery in the sub RAM 103 (S905).

  Next, the sub CPU 102 determines whether or not the sub flag conversion number is any of 23 to 25 (that is, the sub flag conversion combination name is “red 7N”, “red 7SP”, or “GOD”) (S906).

  If it is determined that the sub-flag conversion number is any of 23 to 25 (YES), the sub CPU 102 initializes the normal CZ-pointer counter (S907) and sets the number of GG-pointer games to 0. The game is set (S908), the next game state is set to GG (S909), and the common lottery process is terminated.

  On the other hand, when it is determined that the sub flag conversion number is not any of 23 to 25 (NO), the sub CPU 102 determines whether or not the number of GG predecessor games is 0 (S910). If it is determined that the number of GG precursor games is 0 (YES), the sub CPU 102 ends the common lottery process.

  On the other hand, if it is determined that the number of GG precursor games is not 0 (NO), the sub CPU 102 performs a GG precursor game number lottery to determine the number of GG precursor games by lottery (S911). The result of the number lottery is set to the number of GG precursor games (S912), and the common lottery process is terminated.

<After lottery processing>
FIG. 108 is a flowchart showing the lottery post-processing executed in step S464 of the start command reception processing shown in FIG.

  First, the sub CPU 102 determines whether or not there is a GG continuation rate stocked in the sub RAM 103 (S920). Here, if it is determined that there is a GG continuation rate stocked in the sub RAM 103 (YES), the sub CPU 102 performs lottery with one GG continuation rate among the GG continuation rates stocked in the sub RAM 103. A lottery is performed (S921).

  Next, the sub CPU 102 determines whether or not the continuation rate lottery has been won (S922). If it is determined that the continuation rate lottery is won (YES), the sub CPU 102 adds 1 to the value of the GG counter (S923). On the other hand, when determining that the continuation rate lottery has not been won (NO), the sub CPU 102 deletes the GG continuation rate used for the lottery from the sub RAM 103 (S924).

  In step S920, when it is determined that there is no GG continuation rate stocked in the sub RAM 103 (NO), or after executing the process of step S924, the sub CPU 102 has any of the sub flag conversion numbers 22 to 24 (that is, Then, it is determined whether or not the sub-flag conversion combination name is “Right Red 7”, “Red 7N” or “Red 7SP”) (S925).

  If it is determined that the sub flag conversion number is not any of 22 to 24 (NO), the sub CPU 102 executes the CZ activation process shown in FIG. 109 (S926), and the GG activation process shown in FIG. Is executed (S927), and the lottery post-processing is terminated.

  On the other hand, if it is determined that the sub-flag conversion number is any of 22 to 24 (YES), the sub CPU 102 initializes the number of CZ-pointer games (S928) and initializes the normal CZ-pointer counter ( S929), the number of CZ pre-game signs in the GG is initialized (S930).

  Next, the sub CPU 102 determines whether or not the sub game state is any one of EG, SEG, and PEG (S931). Here, if it is determined that the sub gaming state is any one of EG, SEG, and PEG (YES), the sub CPU 102 ends the lottery post-processing.

  On the other hand, if it is determined that the sub game state is not EG, SEG or PEG (NO), the sub CPU 102 initializes the number of EG games (S932) and sets the next game state to EG (S933). The lottery post-processing is terminated.

<CZ activation processing>
FIG. 109 is a flowchart showing the CZ activation process executed in step S926 of the lottery post-process shown in FIG.

  First, the sub CPU 102 determines whether or not the value of the normal CZ count precursor counter is 0 (S940). Here, if it is determined that the value of the normal CZ precursor sign counter is 0 (YES), the sub CPU 102 initializes the number of CZ lottery games (S941).

  Next, the sub CPU 102 determines whether or not there is CZ1 in the CZ information stock (S942). If it is determined that CZ1 is present in the CZ information stock (YES), the sub CPU 102 sets the next gaming state to CZ1 (S943) and ends the CZ activation process. On the other hand, if it is determined that there is no CZ1 in the CZ information stock (NO), the sub CPU 102 sets the next gaming state to CZ2 (S944) and ends the CZ activation process.

  When it is determined in step S940 that the value of the normal CZ number precursor counter is not 0 (NO), or after executing the processing of step S943 or S944, the sub CPU 102 determines that the value of the CZ number precursor counter in GG is zero. It is determined whether or not (S945).

  Here, when it is determined that the value of the CZ number precursor counter in GG is not 0 (NO), the sub CPU 102 ends the CZ activation process. On the other hand, when it is determined that the value of the CZ pre-sign counter in GG is 0 (YES), the sub CPU 102 initializes the number of CZ lottery games (S946).

  Next, the sub CPU 102 determines whether or not there is CZ3 in the CZ information stock (S947). Here, if it is determined that CZ3 is present in the CZ information stock (YES), the sub CPU 102 sets the next gaming state to CZ3 (S948), and ends the CZ activation process. On the other hand, if it is determined that there is no CZ3 in the CZ information stock (NO), the sub CPU 102 sets the next gaming state to CZ4 (S949) and ends the CZ activation process.

<GG activation process>
FIG. 110 is a flowchart showing the GG activation process executed in step S927 of the lottery post-process shown in FIG.

  First, the sub CPU 102 determines whether or not the number of GG precursor games is 0 (S950). If it is determined that the number of GG precursor games is not 0 (NO), the sub CPU 102 ends the GG activation process.

  On the other hand, if it is determined that the number of GG precursor games is 0 (YES), the sub CPU 102 initializes the number of GG games (S951), sets the next game state to GG (S952), and GG activation processing Exit.

<Output timing of external signal 2>
Next, the output timing of the external signal 2 described above will be described with reference to FIGS. 114 (a) and 114 (b). FIG. 114 (a) is a timing chart of various signals including the external signal 2 when the combination related to GOD1 and GOD2 is displayed on the effective line when the GG is not in the GOD uniform state. On the other hand, FIG. 114B is a timing chart of various signals including the external signal 2 when the combination related to GOD1 and GOD2 is displayed on the active line again during the GG based on the GOD alignment.

  First, in the present embodiment, when the combination relating to GOD1 and GOD2 is displayed on the active line, “100” is set or added to a GOD counter (not shown) as the number of GG games. The GOD counter is a counter that operates when a combination related to GOD1 and GOD2 is displayed on an active line.

  Also, the value of the GOD counter is decremented by “1” every time a unit game is played, and is decremented until it finally becomes “0”. Note that an upper limit value is provided for the value of the GOD counter, and this upper limit value is, for example, “998”.

  Therefore, when the value of the GOD counter is “0”, it indicates that the sub gaming state is not in GG due to GOD matching. On the other hand, when the value of the GOD counter is “1” or more, it indicates that the sub gaming state is GG due to GOD matching. Note that the value of the GOD counter is cleared when the setting is changed in the pachislot machine 1.

  As shown in FIG. 114 (a), when the GOD is not in the GG state, that is, when the combination of GOD1 and GOD2 is displayed on the effective line when the value of the GOD counter is “0”, the payout signal is turned ON. The external signal 2 is turned on, that is, output at the first timing (t1) that is earlier than the timing (t2) by the time between t1 and t2.

  Here, the external signal 2 corresponds to a special combination display signal. The payout signal is included in various signals transmitted to the external device 200 after the end of the unit game, and specifically represents the start of payout of medals due to the combination of GOD1 and GOD2 being displayed on the active line. Signal. The payout signal corresponds to a reference signal.

  As described above, when the sub gaming state when the combination related to GOD1 and GOD2 is displayed on the active line is not in the GG with the GOD uniform, the main CPU 93 performs the first timing (t1) with respect to the payout signal. The external signal 2 is transmitted to the external device 200.

  The external signal 2 turned on at the first timing (t1) is turned off after a predetermined game lock is finished after the medal payout when the combination related to GOD1 and GOD2 is displayed on the active line. .

  On the other hand, as shown in FIG. 114 (b), when the GOD is in GG, that is, when the combination of GOD1 and GOD2 is displayed on the active line when the value of the GOD counter is “1”, the payout The external signal 2 is turned on, that is, output at a second timing (t3) that is earlier than the signal ON timing (t2) by a time between time t3 and time t2.

  Here, the second timing (t3) is different from the first timing (t1), and specifically, is earlier than the first timing (t1) with respect to the ON timing (t2) of the payout signal. It is timing.

  As described above, the main CPU 93 determines the first timing (t1) with respect to the payout signal when the sub gaming state when the combination related to GOD1 and GOD2 is displayed on the active line is GG with the GOD uniform. The external signal 2 is transmitted to the external device 200 at a second timing (t3) different from the above.

  In this case, the external signal 2 turned on at the second timing (t3) is turned off at the timing t4 before the start of paying out medals or at the start of paying out when the combination related to GOD1 and GOD2 is displayed on the active line. Is done. The time from time t3 to time t4 is an arbitrarily set time, for example, 550 msec. The external signal 2 is also turned off when the setting of the pachislot machine 1 is changed.

<Lighting mode of lamp>
Next, lighting modes of the lamps 19L and 19R will be described with reference to FIG. FIG. 115 is a schematic diagram of the lamp 19L. In the following, the lighting mode of the lamp 19L will be described as an example, but the lamp 19R is configured similarly.

  As shown in FIG. 115, the lighting of the lamp 19L is controlled independently for each of the three regions 19a, 19b, 19c. That is, the LED group 25 (see FIG. 3) constituting the lamp 19L is controlled to be lighted independently for each of the three regions 19a, 19b, 19c.

  Here, the three areas 19a, 19b, and 19c are provided corresponding to the upper, middle, and lower areas of the reels 3L, 3C, and 3R provided in the frame of the display window 4 (see FIG. 2). It is a thing. In particular, in the present embodiment, the three regions 19a, 19b, and 19c correspond to the upper, middle, and lower regions of the left reel 3L displayed in the frame of the display window 4L.

  Specifically, of the three areas 19a, 19b, and 19c, the area 19a corresponds to the upper stage of the left reel 3L displayed in the frame of the display window 4L, the area 19b corresponds to the middle stage, and the area 19c. Corresponds to the lower row respectively.

  In the present embodiment, the lamp 19L lights one of the three areas 19a, 19b, and 19c when a predetermined condition is satisfied (for example, when an effect occurs when the GOD button 29 is pressed). Be controlled.

  At this time, when any one of the three regions 19a, 19b, and 19c is lit, the symbol of the left reel 3L corresponding to the lit region (the symbol stopped at any one of the upper, middle, and lower levels). It can be notified that the internal winning combination of the combination including is established.

  For example, if the symbol stopped at the upper stage of the left reel 3L when the area 19a is lit is “GOD1”, it is notified that the internal winning combination of the combination including “GOD1” is established. Thereby, the player can predict the established internal winning combination in advance by visually recognizing the lighting area of the lamp 19L.

  It should be noted that the timing at which the predetermined condition is satisfied may be after the left reel 3L is stopped or before the left reel 3L is stopped. In particular, in the case before the left reel 3L is stopped, compared with the case where the left reel 3L is stopped randomly, the player's The interest for the stop operation can be improved.

  As described above, in the pachislot machine 1 according to the present embodiment, even when the specific condition for shifting the sub gaming state to GG is not satisfied, when the sub gaming state is CZ, the plurality of pachislot machines 1 respectively determined by lottery. If the special transition condition in which the types of the decorative symbols are the same is satisfied, the sub gaming state is shifted to GG, so that it is possible to prevent the player's interest in displaying the decorative symbols from decreasing.

  In addition, the pachislot machine 1 according to the present embodiment enhances the player's interest in the game by increasing the probability that the special transition condition is satisfied when the sub game state is CZ, rather than the specific condition being satisfied. It is possible to improve the operation.

  In addition, the pachislot machine 1 according to the present embodiment determines the decoration symbol to be a lottery as a number group before changing the decoration symbol by lottery, and changes the number of decoration symbols to be a lottery target. Since the probability that the special transition condition is satisfied can be changed when the sub game state is CZ, the player's expectation in CZ can be widened.

  Further, in the pachislot machine 1 according to the present embodiment, when the sub gaming state is CZ, if “mirror” is displayed as a special decoration symbol on the liquid crystal display device 11, the probability that the special transition condition is satisfied becomes high. Therefore, it is possible to improve the interest of the player with respect to the display of decorative symbols.

  In addition, when the sub gaming state is CZ, the pachislot machine 1 according to the present embodiment is displayed on the liquid crystal display device 11 even if the liquid crystal display device 11 does not display the combination of the same type of decorative symbols. If the combination of the decorative patterns made is a predetermined GG winning reach, GG is added.

  Therefore, in the pachislot machine 1 according to the present embodiment, in the unit game in CZ, there is no possibility that the combination of the same type of decorative symbols is displayed before the last decorative symbol is displayed. Even if it exists, a player's expectation can be maintained until the last decoration design is displayed.

  In addition, the pachislot machine 1 according to the present embodiment is displayed on the liquid crystal display device 11 when the combination of decorative symbols of the same type is partly included in the combination of decorative symbols displayed on the liquid crystal display device 11. When the combination of decorated symbols is called a so-called “tempe”, maintaining the same combination of decorative symbols until the next unit game increases the probability that the special transition condition is established in CZ. Therefore, it is possible to improve the player's interest in displaying decorative symbols.

  Further, the pachislot machine 1 according to the present embodiment is displayed on the liquid crystal display device 11 even when the combination of the decorative symbols displayed on the liquid crystal display device 11 partially includes a combination of decorative symbols of the same type. Depending on the combination of decorative symbols, the combination of decorative symbols of the same type is not necessarily maintained until the next unit game, so that the player's interest in displaying the decorative symbols can be further improved.

  Further, the pachislot machine 1 according to the present embodiment not only adds GG according to the result of each unit game in the EG, but also advantageously adds GG to the player according to the number of remaining EG games. In addition, since the number of remaining games of the EG is returned to the specified number of unit games, the player can have various expectations for the games in the EG.

  In addition, the pachislot machine 1 according to the present embodiment adds GG when the history of past unit game results satisfies a predetermined condition, regardless of whether or not the sub game state is EG. Thus, it is possible to make the player have various expectations for the game in EG.

  In addition, the pachislot machine 1 according to the present embodiment displays the history of past unit game results, so that the degree of expectation for the addition of GG even if the player does not store the past unit game results. Can be recognized by the player.

  In addition, the pachislot machine 1 according to the present embodiment, when the sub game state is EG, if a special condition such as winning a lottery corresponding to the internal winning combination is satisfied, until the GG is added, By maintaining the number of remaining EG games over the number of unit games determined by the above, the number of EG unit games increases and the probability of adding GG substantially increases. In this way, players can have more diverse expectations.

  Also, the pachislot machine 1 according to the present embodiment has a history of past unit game results in PEG compared to a case where the history of past unit game results satisfies a predetermined condition in a sub game state other than PEG. When the predetermined condition is satisfied, GG is advantageously added to the player, so that the player can have various expectations for the game in EG.

  In addition, the pachislot machine 1 according to the present embodiment has a special role at the first and second timings that are different from each other depending on whether or not the sub gaming state when the GOD match is displayed is GG due to the GOD match. Since the display signal is transmitted to the external device 200, it is possible to transmit to the external device 200 whether or not the sub game state when the GOD matching to shift to GG is displayed is GG due to the GOD matching. Thereby, on the external device 200 side, it is possible to determine whether or not the GOD alignment is displayed again in the GG due to the GOD alignment.

  Further, the pachislot machine 1 according to the present embodiment determines whether or not the sub gaming state when the GOD match is displayed is GG due to the GOD match according to the reception timing of the special role display signal with respect to the reference signal, for example, the payout signal. Can be transmitted to the external device 200.

  In addition, the pachislot machine 1 according to the present embodiment, when the sub gaming state is CZ, on the condition that the combination of the decorative symbols displayed on the liquid crystal display device 11 is the heaven transition, the next in the CZ After the unit game, since it is relatively easy to shift to GG, it is possible to improve the player's interest in displaying decorative symbols.

  Also, the pachislot machine 1 according to the present embodiment, when the sub game state is CZ, when the same type of decorative symbol combination is maintained up to the next unit game, the stop operation in the next unit game In order to further increase the probability that the special transition condition is established in the CZ by performing lottery of the decorative symbols that are not maintained each time the game is performed, the player's interest in the game in the CZ can be improved. it can.

[Modification]
86 and 87 may be modified as described below with reference to FIGS. 119 and 120. Note that the sub-CPU 102 refers to a table described below when executing a modified example of the CZ mid-process.

<CZ1 button stock lottery table>
The CZ1 button stock lottery table shown in FIG. 116 represents the probability that the number of winning counters to be added to the button counter is determined for each sub-flag lottery combination. In the present embodiment, the number of winning counters is determined in the range from 0 to 5 which is non-winning.

  For example, when the sub flag lottery role is “CU Bell”, “1” is determined with a probability of 24576/32768, “2” is determined with a probability of 6144/32768, and “2” is determined with a probability of 2048/32768. “5” is determined.

<CZ1GG lottery table>
The CZ1GG lottery table shown in FIG. 117 represents the GG winning probability for each sub-flag lottery combination. For example, when the sub-flag lottery combination is “CU Bell”, GG non-winning is determined with a probability of 8192/32768, and GG winning is determined with a probability of 24576/32768.

<CZ1 button counter GG conversion lottery table>
The CZ1GG lottery table shown in FIG. 118 represents GG non-winning and winning probabilities for one value of the button counter. In the present embodiment, GG winning is determined with a probability of 32768/32768.

  Note that the CZ1GG lottery table shown in FIG. 117 is set so that GG wins by the value of the button counter, but non-winning and winning are assigned to one value of the button counter with a predetermined probability. May be set.

<Processing during CZ (Modification)>
FIG. 119 and FIG. 120 are flowcharts showing a modified example of the CZ middle processing shown in FIG. 86 and FIG.

  First, the sub CPU 102 executes the common processing shown in FIGS. 101 and 102 (S960). Next, the sub CPU 102 determines whether or not the number of elapsed games of CZ1 is 0 (S961). If it is determined that the number of elapsed games in CZ1 is 0 (YES), the sub CPU 102 sets 5 for the button stock lottery game number (S962) and sets 1 for the button counter (S963). .

  If it is determined in step S961 that the number of CZ1 elapsed games is not 0 (NO), or after the process of step S963 is completed, the sub CPU 102 adds 1 to the number of CZ1 elapsed games (S964).

  Next, the sub CPU 102 determines whether or not the sub flag conversion number is any of 22 to 24 (that is, the sub flag conversion combination name is “right red 7”, “red 7N”, or “red 7SP”) (S965). ).

  If it is determined that the sub flag conversion number is not any of 22 to 24 (NO), the sub CPU 102 determines whether or not the number of button stock lottery games is 0 (S966).

  If it is determined that the button stock lottery game number is not 0 (NO), the sub CPU 102 subtracts 1 from the button stock lottery game number (S967). Next, the sub CPU 102 refers to the CZ1 button stock lottery table shown in FIG. 116, and performs CZ1 button stock lottery in which the number of button stocks is determined by lottery with a probability corresponding to the sub flag lottery number (S968). Next, the sub CPU 102 adds the number of winning counters to the value of the button counter as a result of the CZ1 button stock lottery (S969), and ends the CZ processing.

  If it is determined in step S966 that the number of button stock lottery games is 0 (YES), the sub CPU 102 refers to the CZ1GG lottery table shown in FIG. 117 and makes a GG with a probability associated with the sub flag lottery number. CZ1GG lottery is performed to determine whether or not the winning is made by lottery (S970).

  Next, the sub CPU 102 determines whether or not the added GG number is 0 (S971). In the present embodiment, if the CZ1GG lottery is won in step S970, the added GG number is set to 1, and if not won, the added GG number is set to 0.

  If it is determined in step S971 that the added GG number is not 0 (NO), the sub CPU 102 adds the added GG number to the value of the GG counter (S972). Next, the sub CPU 102 performs a GG winning allocation lottery for distributing the GG continuation rate (S973).

  Next, the sub CPU 102 stocks the GG continuation rate determined by the GG winning allocation lottery in the sub RAM 103 (S974). If it is determined in step S971 that the number of added GGs is 0 (YES), or after executing the process of step S974, the sub CPU 102 subtracts 1 from the value of the button counter (S975).

  Next, the sub CPU 102 determines whether or not the value of the button counter is 0 (S976). If it is determined that the value of the button counter is not 0 (NO), the sub CPU 102 ends the CZ process.

  On the other hand, when it is determined that the value of the button counter is 0 (YES), the sub CPU 102 determines whether or not the value of the GG counter is 1 or more (S977). If it is determined that the value of the GG counter is not 1 or more (NO), the sub CPU 102 determines whether the number of CZ information stock is 1 or more (S978).

  If it is determined that the number of CZ information stock is 1 or more (YES), the sub CPU 102 performs a normal CZ precursor counter lottery (S979), and the result of the normal CZ precursor counter lottery is normal. The CZ book precursor counter is set (S980).

  In step S978, when it is determined that the number of CZ information stock is not 1 or more (NO), or after executing the process of step S980, the sub CPU 102 sets the next gaming state to normal (S981), and during CZ The process ends.

  If it is determined in step S977 that the value of the GG counter is 1 or more (YES), the sub CPU 102 initializes the number of GG games (S982), and sets 0 to the number of GG precursor games (S983). Then, the next game state is set to GG (S984), and the process during CZ is ended.

  If it is determined in step S965 that the sub flag conversion number is any of 22 to 24 (YES), the sub CPU 102 clears the button stock lottery game number to 0 (S985).

  Next, the sub CPU 102 determines whether or not the value of the button counter is 0 (S986). If it is determined that the value of the button counter is 0 (YES), the sub CPU 102 ends the CZ process.

  On the other hand, when determining that the value of the button counter is not 0 (NO), the sub CPU 102 subtracts 1 from the value of the button counter (S987). Next, the sub CPU 102 performs the CZ button counter GG conversion lottery for performing the GG lottery with the probability shown in the CZ button counter GG conversion lottery table shown in FIG. 118 (S988).

  Next, the sub CPU 102 determines whether or not the GG is won by the CZ button counter GG conversion lottery (S989). If it is determined that GG is won (YES), the sub CPU 102 adds 1 to the value of the GG counter (S990).

  If it is determined in step S989 that the GG has not been won (NO), or after executing the process of step S990, the sub CPU 102 executes the process of step S986.

  In addition, although the process during CZ shown in FIG. 119 and FIG. 120 was described as being executed instead of the process during CZ shown in FIG. 86 and FIG. 87, when the sub game state is CZ1 or CZ3, CZ1 to CZ4 such that the processing in CZ shown in FIGS. 119 and 120 is executed when the processing in CZ shown in FIGS. 86 and 87 is executed and the sub gaming state is CZ2 or CZ4. In contrast, any of the CZ processing may be executed.

  In addition, when it is determined that the sub gaming state shifts to CZ, the sub CPU 102 executes the processing during CZ shown in FIGS. 86 and 87 by the lottery and the sub flag lottery number or the like. Whether to execute the in-CZ process shown at 120 may be selected.

  In the present embodiment, the pachislot machine 1 has been described with respect to an example in which the set number is applied as the number representing the GG period advantageous to the player and the addition number to be added to the GG. The number of games may be applied, the number of notifications (navigation number) for favorably winning a so-called winning combination having different winning modes according to the pressing order, or the number of medals paid out may be applied. It is also possible to apply a net increase number obtained by subtracting the inserted number from the number of medals paid out.

  In the present embodiment, the example in which the gaming machine according to the present invention is applied to the pachislot machine 1 has been described. However, the present invention is not limited to this, and the gaming machine according to the present invention uses a pachinko ball as a gaming medium. The present invention can also be applied to other gaming machines such as gaming machines.

1 Pachislot machine (game machine)
3L, 3C, 3R reel 4, 4L, 4C, 4R display window (design display means)
11 Liquid crystal display device (image display means, game state transition notification means, history display means)
17S Stop switch (stop operation detection means)
51L, 51C, 51R Stepping motor (design variation means, reel stop control means)
56 External concentration terminal board 93 Main CPU (internal winning combination determination means, reel stop control means, winning determination means, status transmission means)
102 sub CPU (game state transition means, game state transition notification means, special mode transition means, decoration symbol determination means, decoration symbol display means, advantageous game state addition means, additional game number setting means)
200 External device

Claims (3)

Multiple reels with multiple symbols,
A symbol display means for displaying a part of a plurality of symbols displayed on the reel;
A symbol changing means for changing the symbol by rotating the reel based on establishment of a predetermined start condition;
An internal winning combination determination means for determining an internal winning combination from a plurality of combinations with a predetermined winning probability based on the establishment of the predetermined start condition;
A stop operation detecting means provided corresponding to the plurality of reels for detecting a stop operation for stopping each reel;
Based on the internal winning combination determined by the internal winning combination determining means and the timing when the stop operation is detected by the stop operation detecting means, the rotation of the reel is stopped and displayed on the symbol display means. Reel stop control means for stopping the fluctuation of the design,
Based on the fact that the change of the symbol is stopped by the reel stop control means, a winning determination for determining whether or not a winning combination is made based on a combination of symbols stopped on an active line provided on the symbol display means. Means,
Image display means for displaying an effect image including a plurality of decorative designs;
When the specific condition is satisfied, the game state is shifted to an advantageous game state advantageous to the player. Gaming state transition means for transitioning the gaming state;
In the added gaming state, on the condition that a predetermined symbol combination is displayed on the symbol display means, the advantageous gaming state is advantageously added to the player according to the number of remaining games in the added gaming state. An advantageous gaming state addition means to perform;
An additional game number setting means for setting the number of remaining games in the added game state to the specified unit game number on the condition that the advantageous game state is added by the advantageous game state adding means;
When the special condition is established in the added gaming state, the added number-of-games setting means sets the added number of games over the unit number of games determined by lottery until the advantageous gaming state is added by the advantageous gaming state adding means. A gaming machine that stops subtracting the number of games in the gaming state.   2. The gaming machine according to claim 1, wherein the advantageous game state adding unit adds the advantageous game state by lottery when a history of past unit game results satisfies a predetermined condition.   The gaming machine according to claim 2, further comprising history display means for displaying a history of the past unit game results.

Images