JP5993926B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine.

  Conventionally, a plurality of reels having a plurality of symbols drawn on the peripheral surface, and a display window for displaying a part of the symbols drawn on the peripheral surfaces of the plurality of reels, the game value such as a medal by the player A gaming machine (a so-called “pachi-slot”) in which symbols are stopped and displayed on the display window by rotating all reels based on the loading operation and starting operation on the start lever, and stopping each reel based on the stop button operation by the player. )It has been known. Such a gaming machine is a player when a predetermined combination of symbols is stopped and displayed on a predetermined line (hereinafter referred to as “effective line”) among symbols displayed on the display window. A privilege (for example, a medal) is given to.

  In addition, such a gaming machine detects the operation of the start lever by the player, extracts a predetermined random number value based on the detection of the operation of the start lever, and extracts the extracted random number value for each winning combination The winning combination is determined based on the winning combination determination table in which the lottery value is defined, and reel stop control is performed based on the determined winning combination and the stop button operation by the player. Here, depending on the determined winning combination, it may be permitted to display a plurality of symbol combinations on the active line among predetermined symbol combinations.

  At this time, when “losing” is determined as the winning combination, a combination of symbols that can receive a privilege is not displayed regardless of the operation of the stop button at any timing. In addition, if the stop button is not operated at an appropriate timing, the winning combination will not be displayed on the active line in combination with the winning combination, or if the stop button is operated at any timing, There is a winning combination in which such a combination of symbols is stopped and displayed on the active line.

  In other words, if the winning combination is determined as a winning combination that does not stop and display the combination of symbols related to the winning combination unless the stop button is operated at the appropriate timing, the stop operation is performed at the appropriate timing. Since it is necessary to do this, the player is required to have a certain skill regarding the operation of the stop button.

  Further, in such a gaming machine, when a predetermined condition is satisfied in a normal state that is disadvantageous to the player, a state advantageous to the player compared to the normal state (hereinafter referred to as “specific state”). ”) Is performed. Here, the “specific state” is a bonus game in which a probability that a combination of symbols from which medals are paid out (hereinafter referred to as “a combination of symbols related to winning a prize”) is displayed on the active line is improved as compared to the normal state. (“RB (regular bonus)”, “BB (big bonus)”, “CB (challenge bonus)”, “MB (middle bonus)”, etc.) If the symbol combination is not displayed (or if the stop button is not operated in the appropriate order, the symbol combination related to the winning combination with the smaller number of medals will be displayed) In addition, “AT (assist time)” that informs the appropriate operation order of the stop button, etc., and operating the start lever without performing the medal insertion operation More re-game the player is started to improve the probability that is determined as a winning combination "RT (replay time)", AT and RT is activated at the same time there is a such as "ART (assisted replay time)". Therefore, the player plays a game while desiring to shift to a specific state advantageous to the player.

  In addition, the gaming machine as described above includes a main control board that controls the game and a sub-control board that controls the production, and is configured to perform control in a distributed manner ( For example, Patent Document 1).

JP 2014-171807 A

  By the way, control related to recent gaming machines tends to become more complicated year by year in order to improve the interest in games. For example, the main control board that controls the game is also configured to improve the interest of the game by performing effects using the reels.

  However, since the capacity that can be mounted on the main control board (especially the main ROM) is a predetermined capacity, while the interest in games is improved, a reduction in capacity has been demanded.

  In view of such circumstances, an object of the present invention is to provide a gaming machine capable of reducing the capacity of a main control board.

In order to solve such a problem, a gaming machine according to the present invention includes a plurality of reels having a plurality of symbols arranged on a peripheral surface, a start operation detecting means for detecting a start operation by a player, and the start operation. A winning combination determining means for determining a winning combination based on the detection of the start operation by the detecting means, and rotating the plurality of reels based on the detection of the starting operation by the start operation detecting means. A reel rotation control means for performing control, a stop operation detection means provided for each of the plurality of reels for detecting a stop operation by a player, and the stop operation detected by the stop operation detection means. If, on the basis of the said winning combination determined by the winning combination determination means, and stop control means for stopping the reel that is rotated by the reel rotation control means, the game control of It includes a main control board to perform, when the predetermined combination of symbols determined to have been displayed, the payout substrate to perform control relating to the payout of game media, the sub-control board for controlling the presentation, the said main The control board transmits a reel stop command having information related to the stop of the reel to the payout board based on the fact that the reel is stopped by the stop control means, and the payout board is connected to the sub-control Based on the fact that the one-way communication to the board is enabled and the reel stop command is received from the main control board, it is determined whether or not the predetermined symbol combination is displayed. A display determination command having information is transmitted to the main control board, and the main control board receives the display determination command from the payout board. Based on the bets, and performing processing to shift a game state.

  Here, the “predetermined symbol combination” may be any symbol combination as long as it is a predetermined symbol combination.

  According to the present invention, a gaming machine capable of reducing the capacity of the main control board can be provided.

It is a figure which shows an example of the front view of a gaming machine. It is a figure which shows an example of the internal structure of a cabinet. It is a figure which shows an example of the back surface of a front door. It is a figure which shows an example of the block diagram of the whole gaming machine. It is a figure which shows an example of an arrangement | sequence data table. It is a figure which shows an example of the symbol combination table in case a symbol combination group is "00". It is a figure which shows an example of the symbol combination table in case a symbol combination group is "01". It is a figure which shows an example of the symbol combination table in case a symbol combination group is "02". It is a figure which shows an example of the relationship of a winning combination, the operation order of a stop button, and winning a prize. It is a figure which shows an example of the winning combination determination table for non-RT gaming states. It is a figure which shows an example of the 1st RT gaming state winning combination determination table. It is a figure which shows an example of the 2nd RT gaming state winning combination determination table during BB. It is a figure which shows an example of the 2nd RT gaming state winning combination determination table for non-BB. It is a figure which shows an example of the 3rd RT gaming state winning combination determination table during BB. It is a figure which shows an example of the 3rd RT gaming state winning combination determination table for non-BB. It is a figure which shows an example of the 4RT gaming state winning combination determination table. It is a figure which shows an example of the 5RT gaming state winning combination determination table. It is a figure which shows an example of the winning combination determination table for RB gaming state in 3rd RT. It is a figure which shows an example of a game state transition diagram. It is a figure which shows an example of the list of the states managed by the main control board. It is a figure which shows an example of the transition diagram of the state managed by the main control board. It is a figure which shows an example of the ART state transfer lottery table for BB winning. It is a figure which shows an example of ART state transfer lottery table in BB. It is a figure which shows an example of the addition lottery table for ART state. It is a figure which shows an example of the BB addition top lottery table. It is a figure which shows an example of an effect determination table. It is a figure which shows an example of the program start process in a main control board. It is a figure which shows an example of the main loop process in a main control board. It is a figure which shows an example of the start lever check process in a main control board. It is a figure which shows an example of the internal lottery process in a main control board. It is a figure which shows an example of the bonus information update process in a main control board. It is a figure which shows an example of the process according to the state at the time of a start in a main control board. It is a figure which shows an example of the process for normal states in a main control board. It is a figure which shows an example of the process for BB states in a main control board. It is a figure which shows an example of the process for 1st fall standby states in a main control board. It is a figure which shows an example of the process for ART preparation states in a main control board. It is a figure which shows an example of the process for ART states in a main control board. It is a figure which shows an example of the process for BB state in ART in the main control board. It is a figure which shows an example of the process for 2nd fall standby states in a main control board. It is a figure which shows an example of the symbol code setting process in a main control board. It is a figure which shows an example of the reel rotation start preparation process in a main control board. It is a figure which shows an example of the reel stop pre-process in a main control board. It is a figure which shows an example of the process during reel rotation in a main control board. It is a figure which shows an example of the display determination command reception standby process in a main control board. It is a figure which shows an example of the medal payout completion command reception standby process in a main control board. It is a figure which shows an example of the game state transfer process in a main control board. It is a figure which shows an example of the process during BB operation | movement in a main control board. It is a figure which shows an example of the process in RB operation | movement in a main control board. It is a figure which shows an example of the process according to the state at the time of a display in a main control board. It is a figure which shows an example of the process for normal states at the time of a display in a main control board. It is a figure which shows an example of the process for BB preparation states at the time of a display in a main control board. It is a figure which shows an example of the process for BB states at the time of a display in a main control board. It is a figure which shows an example of the process for RB states at the time of a display in a main control board. It is a figure which shows an example of the process for the 1st fall standby states at the time of a display in a main control board. It is a figure which shows an example of the process for ART preparation state at the time of display in a main control board. It is a figure which shows an example of the process for BB preparation state during ART at the time of a display in a main control board. It is a figure which shows an example of a process for BB state during ART at the time of display in a main control board. It is a figure which shows an example of the process for RB states during ART at the time of a display in a main control board. It is a figure which shows an example of the process for 2nd fall standby states at the time of a display in a main control board. It is a figure which shows an example of the interruption process in a main control board. It is a figure which shows an example of the input port reading process in a main control board. It is a figure which shows an example of the control command reception process in a main control board. It is a figure which shows an example of the control command transmission process in a main control board. It is a figure which shows an example of the main process in a payout board | substrate. It is a figure which shows an example of the medal reception start process in a payout board | substrate. It is a figure which shows an example of the medal management process in a payout board | substrate. It is a figure which shows an example of the medal insertion check process in a payout board | substrate. It is a figure which shows an example of the storage medal insertion process in a payout board | substrate. It is a figure which shows an example of the display determination process in a payout board | substrate. It is a figure which shows an example of the payout process in a payout board | substrate. It is a figure which shows an example of the interruption process in a payout board | substrate. It is a figure which shows an example of the payment board | substrate input port reading process in a payment board | substrate. It is a figure which shows an example of the delivery board | substrate control command reception process in a delivery board | substrate. It is a figure which shows an example of the delivery board | substrate control command transmission process in a delivery board | substrate. It is a figure which shows an example of the main process in a sub control board. It is a figure which shows an example of the communication process between board | substrates in a sub control board | substrate. It is a figure which shows an example of the command analysis process in a sub control board. It is a figure which shows an example of the process according to command in a sub control board. It is a figure which shows an example of the command list transmitted by the main control board. It is a figure which shows an example of the command list transmitted by the payout board | substrate. It is a figure which shows an example of a switch input signal list. It is a figure which shows an example of the control command reception process in 2nd Embodiment. It is a figure which shows an example of the control command transmission process in 2nd Embodiment. It is a figure which shows an example of the payment board | substrate control command reception process in 2nd Embodiment. It is a figure which shows an example of the payment board | substrate control command transmission process in 2nd Embodiment.

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

(Composition of gaming machine)
First, the configuration of the gaming machine 1 according to the present invention will be specifically described with reference to FIGS. FIG. 1 is a diagram illustrating an example of a front view of a gaming machine, and FIG. 2 is a diagram illustrating an example of an internal structure of a cabinet 2. FIG. 3 is a diagram illustrating an example of the back surface of the front door 3.

(Game machine 1)
The gaming machine 1 in the present embodiment includes a cabinet 2 described later, a front door 3 and the like.

(Cabinet 2)
The cabinet 2 is a substantially rectangular box and has an opening on the front side. A plurality of components are attached to the cabinet 2.

(Front door 3)
The front door 3 is attached so as to close the opening on the front side of the cabinet 2. A plurality of components are attached to the front door 3.

(Hinge mechanism 4)
The hinge mechanism 4 is provided on the left side of the cabinet 2 as viewed from the front, and is provided to pivotally support the front door 3 so that it can be opened and closed.

(Keyhole 5)
The keyhole 5 is provided at the center right side of the front door 3 and is provided for unlocking the front door 3 by a locking device (not shown). Here, when a store clerk or the like of the game store performs maintenance work, changes a set value, or the like, the locking device (not shown) provided on the front door 3 is unlocked. First, a door key (not shown) is inserted into the keyhole 5 of the front door 3 and is unlocked by rotating it by a predetermined angle in the clockwise direction. Next, the front door 3 is opened, and work such as maintenance work and setting value change is performed. When the maintenance work or the work such as changing the set value is completed, the front door 3 is closed and locked.

(Medal slot 6)
The medal slot 6 is provided on the upper left side of the keyhole 5 when viewed from the front, and is provided for a player to insert a medal.

(BET button 7)
The BET button 7 is provided on the left side of the medal insertion slot 6 when viewed from the front, and is provided for using “1” medals among the stored medals in the game.

(MAXBET button 8)
The MAXBET button 8 is provided on the right side of the BET button 7 when viewed from the front, and is provided to use the maximum number of medals that can be used in one game ("1" game) among the stored (credit) medals. It has been. Here, in this embodiment, the maximum value of medals that can be used in one game is “3”.

(Checkout button 9)
The settlement button 9 is provided on the back side of the BET button 7 and is provided for settlement of medals stored (credited) among medals acquired by the player. In the present embodiment, the maximum number of medals that can be stored (credited) is “50”.

(Start lever 10)
The start lever 10 is provided below the BET button 7. The start lever 10 is provided for the player to perform a start operation that triggers the rotation of the left reel 18, the middle reel 19, and the right reel 20 described later. Here, based on the detection of the start operation by the player, the main control board 300 described later starts processing for obtaining a hard random number and rotation of the left reel 18, the middle reel 19, and the right reel 20 described later. The processing to do is performed.

(Left stop button 11)
The left stop button 11 is provided on the right side of the start lever 10 in front view. The left stop button 11 is provided for the player to perform a stop operation that triggers the rotation of the left reel 18 to be described later.

(Intermediate stop button 12)
The middle stop button 12 is provided on the right side of the left stop button 11 when viewed from the front. Further, the middle stop button 12 is provided for the player to perform a stop operation that triggers a stop of the rotation of the middle reel 19 described later.

(Right stop button 13)
The right stop button 13 is provided on the right side of the middle stop button 12 when viewed from the front. The right stop button 13 is provided for the player to perform a stop operation that triggers the rotation of the right reel 20 to be described later.

(Return button 14)
The return button 14 is provided on the right side of the right stop button 13 when viewed from the front. The return button 14 is provided to return a jammed medal when a medal inserted into the medal slot 6 is jammed in a selector 15 described later.

(Selector 15)
The selector 15 is provided on the back side of the front door 3. The selector 15 is provided to determine whether or not the material or shape of the medal inserted into the medal insertion slot 6 is appropriate.

(Error cancel sensor 16s)
The error release sensor 16s is provided on the back side of the keyhole 5, and is provided to release an error that has occurred in the gaming machine 1. Here, the error release sensor 16s includes a light emitting part and a light receiving part, and when a door key (not shown) is inserted into the keyhole 5 and the door key (not shown) is rotated counterclockwise by a predetermined angle, A locking part (not shown) will rotate. And the light-receiving part cannot receive the light emitted from the light-emitting part when the locking part rotates. As a result, the error release sensor 16s detects an error release operation for releasing an error that has occurred in the gaming machine 1.

(Door open / close sensor 17s)
The door opening / closing sensor 17s is provided on the back side of the keyhole 5, and is provided to detect whether or not the front door 3 is open. The door opening / closing sensor 17s includes a light emitting portion and a light receiving portion. When a door key (not shown) is inserted into the keyhole 5 and the door key (not shown) is rotated clockwise by a predetermined angle, the door opening / closing sensor 17s is locked. The part (not shown) will rotate. And the light-receiving part cannot receive the light emitted from the light-emitting part when the locking part rotates. Thereby, the door open / close sensor 17s detects the opening of the front door 3.

(Left reel 18)
The left reel 18 is provided inside the cabinet 2 and has a cylindrical structure. Further, a translucent sheet is mounted on the peripheral surface of the cylindrical structure of the left reel 18, and a plurality of types of symbols are drawn in a row on the sheet. The left reel 18 is rotationally driven by a left stepping motor 151 described later, and a plurality of types of symbols are variably displayed.

(Middle reel 19)
The middle reel 19 is provided inside the cabinet 2 and has a cylindrical structure. Further, a translucent sheet is mounted on the peripheral surface of the cylindrical structure of the middle reel 19, and a plurality of types of symbols are drawn in a row on the sheet. The middle reel 19 is driven to rotate by a middle stepping motor 152, which will be described later, and a plurality of types of symbols are variably displayed.

(Right reel 20)
The right reel 20 is provided inside the cabinet 2 and has a cylindrical structure. In addition, a translucent sheet is mounted on the peripheral surface of the cylindrical structure of the right reel 20, and a plurality of types of symbols are drawn in a row on the sheet. The right reel 20 is rotationally driven by a right stepping motor 153, which will be described later, and a plurality of types of symbols are variably displayed.

(Direction button 21)
The effect button 21 is provided on the right side of the MAXBET button 8 when viewed from the front, and is provided for the player to operate at a predetermined timing. The effect button 21 is connected to an effect button sensor 709s described later. Here, the below-described sub control board 400 controls the later-described liquid crystal display device 45 and the like via the below-described effect control board 600 when the below-described effect button sensor 709s detects the operation of the effect button 21. .

(Cross key 22)
The cross key 22 is provided on the right side of the effect button 21 when viewed from the front. The cross key 22 includes an up button, a down button, a left button, and a right button, and is provided for a player to operate at a predetermined timing. It has been. In addition, a cross key substrate 710 described later is connected to the cross key 22. The sub-control board 400 described later controls the liquid crystal display device 45 described later via the effect control board 600 described later when the cross-key board 710 described later detects the operation of the cross key 22.

(Display window 23)
The display window 23 is provided on the front side of the left reel 18, middle reel 19, and right reel 20, and a plurality of symbols drawn on the peripheral surfaces of the left reel 18, middle reel 19, and right reel 20 can be visually recognized. Is provided to do. Specifically, “3” symbols drawn on the peripheral surface of the left reel 18, “3” symbols drawn on the peripheral surface of the middle reel 19, and drawn on the peripheral surface of the right reel 20. A total of “9” symbols of “3” symbols can be viewed through the display window 23.

(Start lamp 24)
The start lamp 24 is provided above the BET button 7 and is provided to notify whether or not the start operation can be received by the start lever 10. Specifically, the main control board 300 to be described later has a case where the number of medals used in the game is “3” by the operation of the BET button 7 and the MAXBET button 8, or “3” in the medal slot 6. When a medal is inserted, a start operation is started by the start lever 10 by turning on the start lamp 24 when a combination of symbols related to “replay” to be described later is displayed on the active line in the previous game. To notify that it is possible to accept the message.

(Effective line)
Here, in the present embodiment, among the symbols displayed on the display window 23, the effective line is a symbol displayed on the upper stage of the left reel 18, a symbol displayed on the middle stage of the middle reel 19, and the right reel 20. “Right-down line” connecting the symbols displayed in the lower row with a straight line, the symbols displayed in the upper row of the left reel 18, the symbols displayed in the upper row of the middle reel 19, and the upper row of the right reel 20. The “upper line” connecting the displayed symbols with a straight line, the symbol displayed in the middle of the left reel 18, the symbol displayed in the middle of the middle reel 19, and the symbol displayed in the middle of the right reel 20 The “middle line” connected at the right, the symbol displayed at the lower part of the left reel 18, the symbol displayed at the middle part of the middle reel 19, and the symbol displayed at the upper part of the right reel 20 with a straight line “right” "Rising line" and left reel 18 The symbol displayed on the tier, the symbol displayed on the middle tier 19, the “small V line” connecting the symbols displayed on the upper tier of the right reel 20, and the symbol displayed on the tier below the left reel 18. A total of “6” lines including the symbol displayed in the middle stage of the middle reel 19 and the “Oyama line” connecting the symbols displayed in the lower stage of the right reel 20 are effective lines.

  Here, in the present embodiment, among the symbols displayed on the display window 23, the symbol displayed on the lower stage of the left reel 18, the symbol displayed on the lower stage of the middle reel 19, and the symbol displayed on the lower stage of the right reel 20. A line connecting the drawn symbols with a straight line is called a “lower line”. The effective line may be a lower line, in addition to a lower right line, an upper line, a middle line, an upper right line, a small V line, and a small mountain line.

(First BET lamp 25)
The first BET lamp 25 is provided on the right side of the start lamp 24 when viewed from the front, and is provided to notify that the BET number is “1”. Specifically, the main control board 300 to be described later is configured to bet the BET when “1” or more medals are inserted into the medal insertion slot 6 or when “1” or more medals are stored (credit). For example, when the button 7 or the MAXBET button 8 is operated, the first BET lamp 25 is turned on.

(Second BET lamp 26)
The second BET lamp 26 is provided above the first BET lamp 25 and is provided to notify that the BET number is “2”. Specifically, the main control board 300 to be described later is a BET in a case where “2” or more medals are inserted into the medal slot 6 or in a state where “2” or more medals are stored (credit). For example, when the button 7 is operated “2” times, the second BET lamp 26 is turned on.

(3rd BET lamp 27)
The third BET lamp 27 is provided above the second BET lamp 26 and is provided to notify that the BET number is “3”. Specifically, the main control board 300 described later has a MAXBET button when “3” medals are inserted into the medal insertion slot 6 or in a state where “3” or more medals are stored (credit). When No. 8 is operated, the third BET lamp 27 is turned on, for example, when a combination of symbols related to “replay” to be described later is displayed on the active line in the previous game.

(Storage number indicator 28)
The stored number indicator 28 is provided on the right side of the first BET lamp 25, the second BET lamp 26, and the third BET lamp 27 as viewed from the front. The stored number display 28 is provided to display the number of stored (credit) medals of the player stored in the gaming machine 1.

(Payout number display 29)
The payout number indicator 29 is provided on the right side of the stored number indicator 28 in front view. The payout number display 29 is provided for displaying the payout number of medals to be paid out according to the combination of symbols displayed on the active line. The payout number display 29 displays that the gaming machine 1 is in an error state when the gaming machine 1 is in an error state.

(Putable indicator lamp 30)
The insertable display lamp 30 is provided on the right side of the payout number indicator 29 in front view. Here, the main control board 300, which will be described later, performs a process of turning on the insertable display lamp 30 when accepting the insertion of medals through the medal insertion slot 6. On the other hand, when the medal insertion slot 6 does not accept the insertion of medals, the main control board 300 to be described later performs a process of turning off the insertable display lamp 30. Specifically, the insertable display lamp 30 is turned off when the value of the stored number counter described later becomes “50” and the value of the inserted number counter becomes “3”, and step S102 described later is performed. In the game start management process, the light is turned on when the value of the inserted number counter is cleared. As a result, the player is notified through the medal slot 6 whether or not to accept medal insertion.

(Replay display lamp 31)
The replay display lamp 31 is provided below the throwable display lamp 30. Here, the main control board 300 to be described later displays a combination of symbols related to “replay” to be described later on the active line, and a re-game display lamp based on the fact that a re-playing operation flag to be described later is turned on. A process of lighting 31 is performed. On the other hand, the main control board 300 to be described later, when the symbol combination related to “Replay” is not displayed as a game result in the next game in which the symbol combination related to “Replay” to be described later is displayed on the active line In addition, the re-game display lamp 31 is turned off. This notifies that the symbol combination related to “Replay” is displayed on the active line and that the next game can be performed without using a medal.

(Bonus display unit 32)
The Bonus display part 32 is provided on the right side of the display window 23 when viewed from the front. The Bonus display unit 32 is provided with an LED. Here, when a state managed by the main control board 300 described later becomes a BB state, the sub control board 400 described later passes through a panel LED relay board 700 described later and a Bonus display LED board 705 described below. Processing to turn on the LED provided in the Bonus display unit 32 is performed. On the other hand, the sub-control board 400 described later, when the BB state is finished, turns off the LED provided on the Bonus display unit 32 via the panel LED relay board 700 described later and the Bonus display LED board 705 described later. I do. As a result, the player is notified that the player has shifted to the BB state, and the player is informed that the BB state has ended.

(ART display unit 33)
The ART display unit 33 is provided below the Bonus display unit 32. The ART display unit 33 is provided with an LED. Here, when a state managed by a main control board 300 to be described later becomes an ART state, a sub control board 400 to be described later passes through a panel LED relay board 700 to be described later and an ART display LED board 706 to be described later. Processing to turn on the LED provided in the ART display unit 33 is performed. On the other hand, the sub-control board 400 described later, when the ART state is finished, turns off the LED provided on the ART display unit 33 via the panel LED relay board 700 described later and the ART display LED board 706 described later. I do. As a result, the player is notified that the ART state has been entered, and the player has been informed that the ART state has ended.

(Stop button operation display unit 34)
The stop button operation display unit 34 is provided on the left side of the display window 23 when viewed from the front, and (a) a left stop button operation display unit 34L that emits light at a timing when it is optimal to operate the left stop button 11; b) Middle stop button operation display unit 34C that emits light at the timing when it is optimal to operate the middle stop button 12, and (c) Right stop button operation that emits light at the timing that is optimal to operate the right stop button 13 The display unit 34 </ b> R is provided to notify the operation order of the left stop button 11, middle stop button 12, and right stop button 13. Each of the left stop button operation display unit 34L, the middle stop button operation display unit 34C, and the right stop button operation display unit 34R is provided with an LED. Thus, when the state managed by the main control board 300 described later is the ART state, the optimal operation order of the left stop button 11, the middle stop button 12, and the right stop button 13 is notified.

(Left stop button operation display section 34L)
The left stop button operation display unit 34L is provided to notify that it is the optimal timing to operate the left stop button 11. Here, when a state managed by the main control board 300 to be described later is the ART state, the sub control board 400 to be described later will be described later when the left stop button 11 is operated at an optimal timing. A process of turning on an LED provided on the left stop button operation display unit 34L via the panel LED relay board 700 and a stop button operation LED board 707 described later is performed. On the other hand, the sub control board 400 to be described later performs a process of turning on the LED provided in the left stop button operation display unit 34L in the ART state to be described later, and then the operation of the left stop button 11 is performed. Then, a process of turning off the LED provided on the left stop button operation display unit 34L via a panel LED relay board 700 described later and a stop button operation LED board 707 described later is performed. This notifies that it is the optimal timing to operate the left stop button 11.

(Intermediate stop button operation display section 34C)
The middle stop button operation display section 34C is provided to notify that it is the optimal timing to operate the middle stop button 12. Here, when a state managed by the main control board 300 is the ART state, the sub-control board 400 described later has a panel LED described later when the operation of the middle stop button 12 is at an optimal timing. A process of turning on an LED provided on the middle stop button operation display unit 34C via the relay board 700 and a stop button operation LED board 707 described later is performed. On the other hand, the sub-control board 400 described later performs the process of turning on the LED provided in the middle stop button operation display unit 34C in the later-described ART state, and then when the middle stop button 12 is operated. Then, a process of turning off the LEDs provided on the middle stop button operation display unit 34C via a panel LED relay board 700 described later and a stop button operation LED board 707 described later is performed. This notifies that it is the optimal timing to operate the middle stop button 12.

(Right stop button operation display section 34R)
The right stop button operation display unit 34R is provided to notify that it is the optimal timing to operate the right stop button 13. Here, when a state managed by the main control board 300 to be described later is the ART state, the sub control board 400 to be described later will be described later when the right stop button 13 is operated at an optimal timing. A process of turning on an LED provided on the right stop button operation display unit 34R via the panel LED relay board 700 and a stop button operation LED board 707 described later is performed. On the other hand, the sub control board 400 to be described later performs a process of turning on the LED provided in the right stop button operation display unit 34R in the ART state to be described later, and then the operation of the right stop button 13 is performed. Then, a process of turning off an LED provided on the right stop button operation display unit 34R via a panel LED relay board 700 described later and a stop button operation LED board 707 described later is performed. This notifies that it is the optimal timing to operate the right stop button 13. Accordingly, when the state managed by the main control board 300 to be described later is the ART state, the optimal operation order of the left stop button 11, the middle stop button 12, and the right stop button 13 is notified.

(Start lever LED35)
The start lever LED 35 is provided inside the start lever 10. Here, the sub-control board 400 described later performs a process of turning on or blinking the start lever LED 35 via a panel LED relay board 700 described later and a start lever LED board 708 described later at a predetermined timing. As a result, it is possible to perform a visual appeal to the player.

(Lumbar panel 36)
The waist panel 36 is provided below the left stop button 11, the middle stop button 12, and the right stop button 13, and is provided to allow the player to recognize the model name, motif, and the like of the gaming machine 1.
It is

(Tray unit 37)
The saucer unit 37 is provided below the waist panel 36. In addition, the tray unit 37 is provided for receiving and storing medals discharged from a medal payout outlet 38 described later.

(Medal payout exit 38)
The medal payout port 38 is provided below the waist panel 36 and is provided for discharging a medal paid out by a hopper 202 described later when the medal is paid out. Further, the medal payout port 38 is provided for discharging an improper medal when it is determined by a selector sensor 15s described later that the medal inserted into the medal slot 6 is not an appropriate medal. Further, the medal payout opening 38 is inserted at a timing when it is impossible to accept the insertion of the medal when a medal is inserted into the medal insertion slot 6 at a timing when the medal insertion cannot be accepted. It is provided to eject medals.

(Upper left speaker 39)
The upper left speaker 39 is provided on the back side of the front door 3. The upper left speaker 39 is provided for outputting BGM, voice, sound effects, etc. when performing an effect.

(Lower left speaker 40)
The lower left speaker 40 is provided on the back side of the front door 3. The lower left speaker 40 is provided for outputting BGM, voice, sound effects, etc. when performing an effect.

(Upper right speaker 41)
The upper right speaker 41 is provided on the back side of the front door 3. The upper right speaker 41 is provided for outputting BGM, voice, sound effects, etc. when performing an effect.

(Lower right speaker 42)
The lower right speaker 42 is provided on the back side of the front door 3. The lower right speaker 42 is provided to output BGM, voice, sound effects, etc. when performing an effect.

(Setting display section 43)
The setting display unit 43 is provided on a main control board 300 which will be described later, and is provided for displaying a setting value of the gaming machine 1. Here, the main control board 300 to be described later is currently set when the setting change key (not shown) is inserted into the setting change key hole 47 to be described later and rotated clockwise by a predetermined angle. Processing for displaying the set value on the setting display unit 43 is performed.

(Setting change button 44)
The setting change button 44 is provided on a setting switch board 250 described later, and is provided to change a setting value. Here, the main control board 300, which will be described later, displays on the setting display unit 43 when an operation of the setting change button 44 is detected in a state where the currently set value is displayed on the setting display unit 43. A process of switching the displayed set value and displaying it is performed. Note that the currently set value is displayed on the setting display unit 43 when a setting change key switch 48sw described later is turned on. The main control board 300 to be described later performs a process of determining the set value when an operation of the start lever 10 is detected in a state where the currently set value is displayed on the setting display unit 43. . It should be noted that the main control board 300 to be described later performs a process of canceling the error based on the detection of the operation of the setting change button 44 when an error occurs in the gaming machine 1. That is, in the present embodiment, the setting change button 44 has (a) a function for switching the setting value and (b) a function for canceling the error.

  In the present embodiment, the setting values are set in the “6” stage from the setting “1” that is most disadvantageous to the player to the setting “6” that is most advantageous to the player. For this reason, when the operation of the setting change button 44 is detected in the state where the information indicating that the setting is “1” is displayed on the setting display unit 43, the setting display unit 43 indicates that the setting is “2”. Information is displayed, and thereafter, every time the setting change button 44 is operated, the set value displayed on the setting display unit 43 is incremented by “1” and displayed. However, when the setting change button 44 is operated in a state where the information indicating that the setting is “6” is displayed on the setting display unit 43, the information indicating that the setting is “1” is displayed on the setting display unit 43. Will be displayed.

  In the present embodiment, the setting values are set at the “6” stage from the setting “1” to the setting “6”. However, the setting value is not limited to this. For example, the set value may be the “2” stage, the “3” stage, the “4” stage, or the “5” stage.

(Liquid crystal display device 45)
The liquid crystal display device 45 is provided above the left reel 18, the middle reel 19, and the right reel 20, and is provided for displaying moving images, still images, and the like. Here, the sub-control board 400 described later is one of “push order bell A to push order bell E” by the internal lottery process described later when the state managed by the main control board 300 described later is the ART state. Is determined, the operation sequence of the left stop button 11, the middle stop button 12, and the right stop button 13 is displayed on the liquid crystal display device 45 via the effect control board 600.

(External concentration terminal board 46)
The external concentration terminal board 46 is provided on the lower right side of the setting switch board 250, which will be described later, and (a) the number of medals used in the game with respect to the outside of the gaming machine 1 such as a hall computer (not shown). (B) a medal payout signal that can specify the number of medals paid out to the player, and (c) that the state managed by the main control board 300 described later has shifted to the ART state. (D) a BB state signal that can specify that a state managed by the main control board 300 described later has shifted to the BB state, and (e) that an illegal act has been performed. Provided to transmit a secure security signal.

(Setting change keyhole 47)
The setting change keyhole 47 is provided on a setting switch board 250 to be described later, and is provided to change a setting value. Further, a setting change key switch 48sw, which will be described later, detects that the setting change key (not shown) is rotated by a predetermined angle in the clockwise direction with the setting change key (not shown) inserted in the setting change key hole 47. Is provided.

(Status board 100)
The status board 100 is provided on the back side of the front door 3 and below the display window 23. The status board 100 also includes a BET switch 7sw described later, a MAXBET switch 8sw described later, a settlement switch 9sw described later, a start switch 10sw described later, a left stop switch 11sw described later, a middle stop switch 12sw described later, and a right stop described later. A switch 13sw, a selector sensor 15s, an error release sensor 16s, a door opening / closing sensor 17s, a start lamp 24, a first BET lamp 25, a second BET lamp 26, a third BET lamp 27, a stored number indicator 28, a payout number indicator 29, A throwable display lamp 30, a replay display lamp 31, a main control board 300 to be described later, and a payout board 350 to be described later are connected.

(Reel control board 150)
The reel control board 150 is provided above the left reel 18, the middle reel 19, and the right reel 20, and is provided to control the rotation and stop of the left reel 18, the middle reel 19, and the right reel 20. . The reel control board 150 includes a left stepping motor 151 to be described later, a middle stepping motor 152 to be described later, a right stepping motor 153 to be described later, a left reel sensor 154s to be described later, a middle reel sensor 155s to be described later, and a right reel sensor 156s to be described later. , And a main control board 300 to be described later are connected.

(Left stepping motor 151)
The left stepping motor 151 is provided inside the left reel 18 and is provided for controlling the left reel 18. The left stepping motor 151 has a configuration capable of stopping the rotation shaft at a specified angle. As a result, the left reel 18 rotates at a constant angle each time a pulse signal is output to the left stepping motor 151. The main control board 300 manages the rotation angle of the left reel 18 by counting the number of times the pulse signal is output to the left stepping motor 151 after detecting the reel index.

(Medium stepping motor 152)
The middle stepping motor 152 is provided inside the middle reel 19 and is provided for controlling the middle reel 19. Further, the middle stepping motor 152 has a configuration capable of stopping the rotation axis at a specified angle. As a result, the intermediate reel 19 rotates at a constant angle each time a pulse signal is output to the intermediate stepping motor 152. The main control board 300 manages the rotation angle of the middle reel 19 by counting the number of times the pulse signal is output to the middle stepping motor 152 after detecting the reel index.

(Right stepping motor 153)
The right stepping motor 153 is provided inside the right reel 20 and is provided for controlling the right reel 20. The right stepping motor 153 has a configuration capable of stopping the rotation shaft at a specified angle. As a result, the right reel 20 rotates at a constant angle each time a pulse signal is output to the right stepping motor 153. The main control board 300 manages the rotation angle of the right reel 20 by counting the number of times the pulse signal is output to the right stepping motor 153 after detecting the reel index.

(Left reel sensor 154s)
The left reel sensor 154s is provided inside the left reel 18, and includes an optical sensor having a light emitting part and a light receiving part. The left reel sensor 154s is provided to detect a reel index indicating that the left reel 18 has rotated “1”.

(Medium reel sensor 155s)
The middle reel sensor 155s is provided inside the middle reel 19, and includes an optical sensor having a light emitting part and a light receiving part. The middle reel sensor 155s is provided to detect a reel index indicating that the middle reel 19 has rotated “1”.

(Right reel sensor 156s)
The right reel sensor 156s is provided inside the right reel 20, and includes an optical sensor having a light emitting part and a light receiving part. The right reel sensor 156s is provided to detect a reel index indicating that the right reel 20 has rotated “1”.

(Power supply board 200)
The power supply board 200 is provided inside the cabinet 2 on the left side when viewed from the front, and is provided for performing control for supplying power to the gaming machine 1. The power supply board 200 is connected to a power switch 201sw, a hopper 202, an auxiliary storage sensor 203s, a main control board 300, and a payout board 350, which will be described later.

(Power button 201)
The power button 201 is provided on the left side of a front view of a hopper 202 described later, and is provided for performing an operation of supplying power to the gaming machine 1.

(Hopper 202)
The hopper 202 is provided on the right side of the power supply board 200 as viewed from the front, and is provided for paying out medals to the player. Here, the payout board 350, which will be described later, performs a process of driving the hopper 202 via the power supply board 200 when a combination of symbols for paying out medals is displayed on the active line, and gives a medal to the player. Process to pay out.

(Auxiliary storage 203)
The auxiliary storage 203 is provided on the right side of the hopper 202 as viewed from the front, and is provided to store the overflowing medals when the medals stored in the hopper 202 overflow.

(Setting switch board 250)
The setting switch board 250 is provided inside the cabinet 2 and on the upper right side of the cabinet 2 when viewed from the front. Further, a setting change switch 44sw described later and a setting change key switch 48sw described later are connected to the setting switch board 250.

(Main control board 300)
The main control board 300 is provided inside the cabinet 2 and on the left side of the setting switch board 250 when viewed from the front, and is provided for controlling the gaming machine 1. The main control board 300 includes a main CPU 301 described later, a main ROM 302 described later, a main RAM 303 described later, and a main random number generator 304 described later. Further, the main control board 300 includes a setting display unit 43, an external concentration terminal board 46, a status board 100, a reel control board 150, a power supply board 200, a setting switch board 250, a later-described payout board 350, and a later-described sub control board. 400 is connected.

(Dispensing board 350)
The payout board 350 is provided on the back side of a sub-control board 400 described later, and is provided for performing payout control of game media such as medals. In addition, the payout board 350 controls the medal insertion control and the settlement control when a game medium such as a medal is inserted by the player, or when the operation of the BET button 7, the MAXBET button 8, and the settlement button 9 is detected. Is provided to do. Here, the payout board 350 includes a payout CPU 351, a payout ROM 352, a payout RAM 353, and a payout random number generator 354. Further, a status board 100, a power supply board 200, a main control board 300, and a later-described sub control board 400 are connected to the payout board 350.

  In the present embodiment, the main control board 300 and the payout board 350 are both provided on the cabinet 2 side, not on the front door 3 side. Thereby, compared with the case where the main control board 300 and the payout board 350 are separately provided on the cabinet 2 side and the front door 3 side, the harness connecting the main control board 300 and the payout board 350 can be shortened. it can.

(Sub control board 400)
The sub-control board 400 is provided on the left side of the main control board 300 when viewed from the front, and is provided mainly for controlling the production. The sub control board 400 includes a sub CPU 401 described later, a sub ROM 402 described later, a sub RAM 403 described later, and a sub random number generator 404 described later. Further, a main control board 300, a payout board 350, a backlight relay board 450 described later, an effect control board 600 described later, and a panel LED relay board 700 described later are connected to the sub control board 400.

(Backlight relay board 450)
The backlight relay board 450 is provided below the main control board 300, and relays between the sub control board 400, a left backlight board 451 described later, a middle backlight board 452 described later, and a right backlight board 453 described later. Is provided to do. In addition, a sub-control board 400, a later-described left backlight board 451, a later-described middle backlight board 452, and a later-described right backlight board 453 are connected to the backlight relay board 450.

(Left backlight substrate 451)
The left backlight substrate 451 is provided inside the left reel 18 and is connected to a left backlight 461 described later. Further, the left backlight substrate 451 is provided for performing light emission control of the left backlight 461 described later from the sub control substrate 400 via the backlight relay substrate 450.

  In FIG. 2, a left stepping motor 151, a middle stepping motor 152, a right stepping motor 153, a left reel sensor 154s, a middle reel sensor 155s, a right reel sensor 156s, a left backlight board 451, a middle backlight board 452, and a right In order to describe the backlight substrate 453, illustration of sheets mounted on the left reel 18, the middle reel 19, and the right reel 20 is omitted.

(Medium backlight substrate 452)
The middle backlight substrate 452 is provided inside the middle reel 19 and is connected to a middle backlight 462 described later. The middle backlight board 452 is provided for performing light emission control of the middle backlight 462, which will be described later, from the sub control board 400 via the backlight relay board 450.

(Right backlight substrate 453)
The right backlight substrate 453 is provided inside the right reel 20, and a right backlight 463 described later is connected thereto. Further, the right backlight substrate 453 is provided for performing light emission control of the right backlight 463 described later from the sub control substrate 400 via the backlight relay substrate 450.

(Amplifier board 500)
The amplifier board 500 is provided above the upper left speaker 39 and outputs BGM data, audio data, sound effect data, and the like from the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. It is provided to perform control. The amplifier board 500 is connected with an upper left speaker 39, a lower left speaker 40, an upper right speaker 41, a lower right speaker 42, and an effect control board 600 described later.

(Director drive relay board 550)
The effect device drive relay board 550 is provided above the effect control board 600 described later, and is provided to relay the effect control board 600 described later and the LED control board 650 described later. In addition, an effect control board 600 described later and an LED control board 650 described later are connected to the effect device drive relay board 550.

(Production control board 600)
The effect control board 600 is provided above the back surface of the front door 3 and is provided mainly for executing an effect. The effect control board 600 includes a liquid crystal control CPU 601 described later, a liquid crystal control ROM 602 described later, a liquid crystal control RAM 603 described later, a CGROM 604 described later, a sound source IC 605 described later, a sound source ROM 606 described later, and a VDP 607 described later. Further, the effect control board 600 is connected with the liquid crystal display device 45, the sub control board 400, the amplifier board 500, and the effect device drive relay board 550.

(Top LED board 651)
The top LED board 651 is provided above the effect control board 600 and is provided to control the top LED 661 described later. The top LED board 651 is connected to a rendering device drive relay board 550 and a later-described top LED 661.

(Corner LED board 652)
The corner LED boards 652 are provided on the left and right sides of the rendering device drive relay board 550, and are provided for controlling the corner LEDs 662 described later. In addition, the corner LED board 652 is connected to a rendering device drive relay board 550 and a corner LED 662 described later.

(Side LED board 653)
The side LED boards 653 are provided on the back side of the front door 3 and on both the left and right sides of the display window 23, and are provided for controlling the side LEDs 663 described later. The side LED board 653 is connected to a rendering device drive relay board 550 and a side LED 663 described later.

(Tray side LED board 654)
The saucer side LED board 654 is provided on the back side of the front door 3, outside the left lower speaker 40 and outside the right lower speaker 42, and is provided for controlling the saucer side LED 664 described later. ing. In addition, to the saucer side LED board 654, a rendering device drive relay board 550 and a later-described saucer side LED 664 are connected.

(Receiver LED board 655)
The saucer LED substrate 655 is provided on the back side of the front door 3 and on the back side of the saucer unit 37, and is provided for controlling a saucer LED 665 described later. Further, the receiving device LED relay board 655 is connected to a rendering device drive relay board 550 and a receiving tray LED 665 described later.

(Top LED 661)
The top LED 661 is provided above the liquid crystal display device 45. The top LED 661 is designed and designed with shapes, colors, patterns, patterns, etc. appealing to the player's vision. Here, the sub control board 400 performs a process of turning on and blinking the top LED 661 through the effect device drive relay board 550, the effect control board 600, and the top LED board 651. Thereby, the effect which appeals visually to a player can be performed.

(Corner LED 662)
The corner LEDs 662 are provided on both the left and right sides of the liquid crystal display device 45. Further, the corner LED 662 is designed and designed with a shape and color appealing to the player's vision, a pattern, a picture, and the like. Here, the sub control board 400 performs a process of turning on and blinking the corner LED 662 via the effect device drive relay board 550, the effect control board 600, and the corner LED board 652. Thereby, the effect which appeals visually to a player can be performed.

(Side LED 663)
The side LEDs 663 are provided at the left and right ends of the gaming machine 1. Further, the side LED 663 is designed and designed with a shape, color, pattern, pattern and the like appealing to the player's vision. Here, the sub control board 400 performs a process of turning on and blinking the side LED 663 via the effect device drive relay board 550, the effect control board 600, and the side LED board 653. Thereby, the effect which appeals visually to a player can be performed.

(Tray side LED 664)
The tray side LED 664 is provided below the side LED 663. In addition, the tray side LED 664 is designed and designed with a shape, color, pattern, pattern, etc. appealing to the player's vision. Here, the sub control board 400 performs a process of lighting and blinking the saucer side LED 664 via the effect device drive relay board 550, the effect control board 600, and the saucer side LED board 654. Thereby, the effect which appeals visually to a player can be performed.

(Tray LED 665)
The saucer LED 665 is provided on the front side of the saucer unit 37 in front view. The tray LED 665 is designed and designed with shapes, colors, patterns, patterns, etc. appealing to the player's vision. Here, the sub control board 400 performs a process of lighting and blinking the saucer LED 665 via the effect device drive relay board 550, the effect control board 600, and the saucer LED board 655. Thereby, the effect which appeals visually to a player can be performed.

(Comparator LED relay board 700)
The panel LED relay board 700 is provided above the lower left speaker 40, and includes a sub control board 400, a MAXBET button LED board 701, which will be described later, a stop button LED board 702, which will be described later, an effect button LED board 703, which will be described later. Waist panel LED board 704, later-described Bonus display LED board 705, later-described ART display LED board 706, later-described stop button operation LED board 707, later-described start lever LED board 708, later-described effect button sensor 709s, later-described cross It is provided to relay the key board 710. The panel LED relay board 700 includes a sub control board 400, a MAXBET button LED board 701, which will be described later, a stop button LED board 702, which will be described later, an effect button LED board 703, which will be described later, a waist panel LED board 704, which will be described later. A Bonus display LED substrate 705, an ART display LED substrate 706 described later, a stop button operation LED substrate 707 described later, a start lever LED substrate 708 described later, an effect button sensor 709s described later, and a cross key substrate 710 described later are connected.

(Block diagram of the entire gaming machine)
Next, a block diagram of the entire gaming machine 1 will be described with reference to FIG.

  In the gaming machine 1, the status board 100, the reel control board 150, the power board 200, the setting switch board 250, the payout board 350, and the sub control board 400 are connected to the main control board 300 that controls the main operation of the gaming machine 1. Has been.

(BET switch 7sw)
The BET switch 7sw is a switch for detecting the operation of the BET button 7. Here, the status board 100 transmits a BET switch input signal to the main control board 300 and the payout board 350 when an operation of the BET button 7 is detected by the BET switch 7sw. The main control board 300 performs a process of executing the spinning effect based on the reception of the BET switch input signal from the status board 100 when executing the spinning effect described later, and the first BET lamp 25. Then, lighting control of the second BET lamp 26 and the third BET lamp 27 and subtraction display control of the stored number display displayed on the stored number display 28 are performed. Further, the payout board 350 performs a process of using “1” medals from the stored (credit) medals based on the reception of the BET switch input signal from the status board 100.

(MAXBET switch 8sw)
The MAXBET switch 8sw is a switch for detecting the operation of the MAXBET button 8. Here, the status board 100 transmits a MAXBET switch input signal to the main control board 300 and the payout board 350 when the operation of the MAXBET button 8 is detected by the MAXBET switch 8sw. The main control board 300 performs the process of executing the spinning effect based on the reception of the MAXBET switch input signal from the status board 100 when executing the spinning effect described later, and the first BET lamp 25. Then, lighting control of the second BET lamp 26 and the third BET lamp 27 and subtraction display control of the stored number display displayed on the stored number display 28 are performed. Further, the payout board 350 performs a process of using “3” medals from the stored (credit) medals based on the reception of the MAXBET switch input signal from the status board 100.

(Settlement switch 9sw)
The settlement switch 9sw is a switch for detecting the operation of the settlement button 9. Here, the status board 100 transmits a settlement switch input signal to the payout board 350 when an operation of the settlement button 9 is detected by the settlement switch 9sw. Then, the payout board 350 performs a process of paying out the stored (credit) medal based on the receipt of the checkout switch input signal from the status board 100. Specifically, the payout board 350 transmits a signal to the effect that the stored (credit) medal is returned to the power supply board 200. Then, the power supply substrate 200 performs a process of returning the stored medals by driving the hopper 202.

  In the present embodiment, the settlement switch input signal is transmitted only to the payout board 350, but the present invention is not limited to this. For example, the adjustment switch input signal may be transmitted to the main control board 300. In this case, the main control board 300 is controlled to turn off the first BET lamp 25, the second BET lamp 26, and the third BET lamp 27 based on the receipt of the settlement switch input signal and displayed on the stored number display 28. Subtraction display control of the number of stored sheets is performed.

(Start switch 10sw)
The start switch 10sw is a switch for detecting the operation of the start lever 10. Here, the status board 100 transmits a start switch input signal to the main control board 300 when an operation of the start lever 10 is detected by the start switch 10sw. Based on the reception of the start switch input signal from the status board 100, the main control board 300 starts the rotation of the left reel 18, the middle reel 19, and the right reel 20, the start lamp 24, and the input possible display. The lamp 30 is turned off.

(Left stop switch 11sw)
The left stop switch 11sw is a switch for detecting an operation of the left stop button 11. Here, the status board 100 transmits a left stop switch input signal to the main control board 300 when an operation of the left stop button 11 is detected by the left stop switch 11sw. The main control board 300 performs a process of stopping the rotating left reel 18 based on the reception of the left stop switch input signal from the status board 100.

(Intermediate stop switch 12sw)
The middle stop switch 12sw is a switch for detecting the operation of the middle stop button 12. Here, the status board 100 transmits an intermediate stop switch input signal to the main control board 300 when the operation of the intermediate stop button 12 is detected by the intermediate stop switch 12sw. The main control board 300 performs a process of stopping the rotating middle reel 19 based on the reception of the middle stop switch input signal from the status board 100.

(Right stop switch 13sw)
The right stop switch 13sw is a switch for detecting the operation of the right stop button 13. Here, the status board 100 transmits a right stop switch input signal to the main control board 300 when the operation of the right stop button 13 is detected by the right stop switch 13sw. Then, the main control board 300 performs processing for stopping the rotating right reel 20 based on the reception of the right stop switch input signal from the status board 100.

(Selector sensor 15s)
The selector sensor 15 s is a sensor for detecting that an appropriate medal is inserted into the medal insertion slot 6. Here, the status board 100 transmits a selector sensor input signal to the payout board 350 when the selector sensor 15s detects the passage of a normal medal. Then, the payout board 350 is used for (a) adding “1” to the number of medals to be stored (credited) based on the reception of the selector sensor input signal from the status board 100, or (b) used in the game. A process of adding “1” to the number of medals to be performed is performed.

  In this embodiment, the selector sensor input signal is transmitted only to the payout board 350, but the present invention is not limited to this. For example, the selector sensor input signal may be transmitted to the main control board 300 as well. In this case, the main control board 300 controls the lighting of the first BET lamp 25, the second BET lamp 26, and the third BET lamp 27 based on the reception of the selector sensor input signal and is displayed on the stored number display 28. Addition display control of the stored number display is performed.

(Setting change switch 44sw)
The setting change switch 44sw is a switch for detecting an operation of the setting change button 44. Here, the setting switch board 250 transmits a predetermined signal to the main control board 300 when an operation of the setting change button 44 is detected by the setting change switch 44sw. The main control board 300 performs processing to update and display the setting value displayed on the setting display unit 43 based on the reception of a predetermined signal from the setting switch board 250.

(Setting change key switch 48sw)
The setting change key switch 48sw is a switch for detecting that a setting change key (not shown) is rotated by a predetermined angle in a state where the setting change key (not shown) is inserted into the setting change key hole 47. Here, when it is detected that the setting switch board 250 is rotated by a predetermined angle in a state where a setting change key (not shown) is inserted into the setting change key hole 47, the setting switch board 250 is connected to the main control board 300. To transmit a predetermined signal. The main control board 300 performs processing for displaying the current set value on the setting display unit 43 based on the reception of a predetermined signal from the setting switch board 250.

(Power switch 201sw)
The power switch 201sw is a switch for detecting an operation of the power button 201. Here, the power supply board 200 performs a process of supplying power to the gaming machine 1 when the operation of the power button 201 is detected by the power switch 201sw.

(Hopper sensor 202s)
The hopper sensor 202s is a sensor for detecting that a medall to be paid out has passed when the hopper 202 is driven. Here, the power supply board 200 transmits a hopper sensor input signal to the payout board 350 when the hopper sensor 202s detects the payout of medals. Then, the payout board 350 performs a process of subtracting the payout number based on the reception of the hopper sensor input signal from the status board 100.

(Auxiliary storage sensor 203s)
The auxiliary storage sensor 203s is a sensor for detecting that medals stored in the auxiliary storage 203 are full. Here, when the auxiliary storage sensor 203s detects that the medal stored in the auxiliary storage 203 is full, the power supply board 200 sends an auxiliary storage sensor input signal to the main control board 300. Send. The main control board 300 performs error processing when the medals stored in the auxiliary storage 203 are full based on the reception of the auxiliary storage sensor input signal from the power supply board 200.

(Main CPU 301)
The main CPU 301 is provided on the main control board 300. Further, the main CPU 301 reads a program stored in a main ROM 302, which will be described later, and performs predetermined arithmetic processing in accordance with the progress of the game, so that the status board 100, the reel control board 150, the power board 200, and the payout board 350. Then, a predetermined signal is transmitted to the sub control board 400.

(Main ROM 302)
The main ROM 302 is provided on the main control board 300. The main ROM 302 is provided for storing a control program executed by the main CPU 301, a data table, data for transmitting commands to the payout board 350 and the sub control board 400, and the like. Specifically, the main ROM 302 includes an array data table (see FIG. 5) described later, a non-RT gaming state winning combination determination table (see FIG. 10) described later, and a first RT gaming state winning combination determination table (see FIG. 5). 11), a second RT gaming state winning combination determination table (see FIG. 12), which will be described later, a non-BB second RT gaming state winning combination determination table (see FIG. 13), which will be described later, and a third RT game during BB, which will be described later. State winning combination determination table (see FIG. 14), non-BB third RT gaming state winning combination determination table (see FIG. 15), which will be described later, fourth RT gaming state winning combination determination table (see FIG. 16), which will be described later, and later 5RT gaming state winning combination determination table (see FIG. 17), RB gaming state winning combination determination table (see FIG. 18) to be described later, and BB winning state ART state transition lottery table to be described later. (See FIG. 22), a later-described ART state transition lottery table (see FIG. 23), an ART state additional lottery table (see FIG. 24), a later-described BB intermediate addition lottery table (see FIG. 25), and the like. I remember it.

(Main RAM 303)
The main RAM 303 is provided on the main control board 300. The main RAM 303 is provided for storing various data determined by the execution of the program by the main CPU 301. Specifically, the main RAM 303 is provided with various storage areas such as various counters such as an insertion number counter and a setting change device operation abnormality flag storage area.

(Main random number generator 304)
The main random number generator 304 is provided on the main control board 300. The main random number generator 304 is provided for generating a random number used in a lottery or the like for determining a winning combination. Here, in the present embodiment, the main random number generator 304 generates a random number value in the range of “0” to “65535”.

(Payout CPU 351)
The payout CPU 351 is provided on the payout board 350. In addition, the payout CPU 351 reads a program stored in a payout ROM 352, which will be described later, and performs predetermined arithmetic processing in accordance with the progress of the game, so that the status board 100, the power supply board 200, the main control board 300, and the sub control board. A predetermined signal is transmitted to 400.

(Discharge ROM 352)
The payout ROM 352 is provided on the payout board 350. The payout ROM 352 is provided to store a control program executed by the payout CPU 351, a data table, data for transmitting commands to the main control board 300 and the sub control board 400, and the like. Specifically, the payout ROM 352 includes a symbol combination table (see FIG. 6) whose symbol combination group described later is “00”, a symbol combination table whose reference symbol combination group is “01” (see FIG. 7), and a symbol described later. A symbol combination table (see FIG. 8) having a combination group of “02” is stored.

(Payout RAM 353)
The payout RAM 353 is provided on the payout board 350. The payout RAM 353 is provided for storing various data determined by the execution of the program by the payout CPU 351. Specifically, the payout RAM 353 is provided with various storage areas such as various counters such as an inserted number counter and a re-game operating flag storage area.

(Sub CPU 401)
The sub CPU 401 is provided on the sub control board 400. Also, the sub CPU 401 reads a program stored in a sub ROM 402 described later, information on commands received from the main control board 300 and the payout board 350, and information on errors received from the main control board 300 and the payout board 350. , Provided to perform a predetermined calculation based on signals input from the effect button sensor 709s and the cross key board 710 and supply the result of the calculation to the backlight relay board 450, the effect control board 600, and the like. Yes.

(Sub ROM 402)
The sub ROM 402 is provided on the sub control board 400. The sub ROM 402 is provided for storing a control program executed by the sub CPU 401, a data table, and the like. Specifically, the sub ROM 402 stores an effect determination table (see FIG. 26) described later.

(Sub RAM 403)
The sub RAM 403 is provided on the sub control board 400. The sub RAM 403 is provided for storing various data determined by the execution of the program by the sub CPU 401. Specifically, the sub-RAM 403 is provided with an effect information storage area for storing information related to effects determined in an effect determination table (see FIG. 26) described later.

(Sub-random number generator 404)
The sub random number generator 404 is provided on the sub control board 400. The sub-random number generator 404 is provided for generating a random number used in a lottery or the like for determining the production. Here, in the present embodiment, the sub-random number generator 404 generates a random value in the range of “0” to “65535”.

(Left backlight 461)
The left backlight 461 is provided on the left backlight substrate 451 and includes a plurality of LEDs. Here, the sub control board 400 performs a process of causing the left backlight 461 to emit light via the backlight relay board 450 and the left backlight board 451. Thereby, the visual recognition of the symbol of the left reel 18 becomes easy.

(Medium backlight 462)
The middle backlight 462 is provided on the middle backlight substrate 452 and includes a plurality of LEDs. Here, the sub-control board 400 performs a process of causing the middle backlight 462 to emit light via the backlight relay board 450 and the middle backlight board 452. Thereby, the visual recognition of the design of the middle reel 19 is facilitated.

(Right backlight 463)
The right backlight 463 is provided on the right backlight substrate 453 and includes a plurality of LEDs. Here, the sub-control board 400 performs a process of causing the right backlight 463 to emit light via the backlight relay board 450 and the right backlight board 453. Thereby, the visual recognition of the design of the right reel 20 is facilitated.

(LCD control CPU 601)
The liquid crystal control CPU 601 is provided on the effect control board 600. The liquid crystal control CPU 601 is provided for reading a program stored in a liquid crystal control ROM 602 described later and creating a display list based on a signal received from the sub control board 400. The liquid crystal control CPU 601 performs control to display image data stored in a CGROM 604 described later on the liquid crystal display device 45.

(LCD control ROM 602)
The liquid crystal control ROM 602 is provided on the effect control board 600. The liquid crystal control ROM 602 is provided to store a control program executed by the liquid crystal control CPU 601, a data table, and the like. Specifically, the liquid crystal control ROM 602 includes a control processing program of the liquid crystal control CPU 601, a display list generation program for generating a display list, a combination of animation scenes that are referred to when displaying an animation, and an animation scene display order. A weight frame indicating an image display time, various target data such as a sprite identification number and a transfer source address, various parameters such as a sprite display position and a transfer destination address, a drawing method, and the like are stored.

(Liquid crystal control RAM 603)
The liquid crystal control RAM 603 is provided on the effect control board 600. The liquid crystal control RAM 603 functions as a data work area when the liquid crystal control CPU 601 performs arithmetic processing, and is provided to temporarily store data read from the liquid crystal control ROM 602.

(CGROM604)
The CGROM 604 is provided on the effect control board 600. The CGROM 604 includes color number information for specifying a color number for each pixel in a predetermined range of pixels (for example, “32” pixels × “32” pixels) and an α value indicating the transparency of the image. It is provided for compressing and storing image data comprising a set.

(Sound source IC 605)
The sound source IC 605 is provided on the effect control board 600. The sound source IC 605 reads a program and data relating to sound stored in a sound source ROM 606, which will be described later, and generates sound signals for driving the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. It is provided for.

(Sound source ROM 606)
The sound source ROM 606 is provided on the effect control board 600. The sound source ROM 606 is provided for storing a program, data, and the like related to a sound output when performing an effect.

(VDP607)
The VDP 607 is a so-called image processor, and controls to read image data from the “display frame buffer area” out of the first frame buffer area and the second frame buffer area based on an instruction from the liquid crystal control CPU 601. Then, control for displaying an image on the liquid crystal display device 45 is performed by generating a video signal (for example, LVDS signal or RGB signal) based on the read image data. The VDP 607 includes a control register (not shown), a CG bus interface, a CPU interface, a clock generation circuit, an expansion circuit, a drawing circuit, a display circuit, a memory controller, and the like, which are connected by a bus.

(LED control board 650)
The LED control board 650 is provided to control the top LED 661, corner LED 662, side LED 663, saucer side LED 664, and saucer LED 665. In addition, to the LED control board 650, a rendering device drive relay board 550, a top LED board 651, a corner LED board 652, a side LED board 653, a saucer side LED board 654, and a saucer LED board 655 are connected.

(MAXBET button LED board 701)
The MAXBET button LED substrate 701 is connected to a MAXBET button LED 721 described later, and is provided for performing processing of emitting a MAXBET button LED 721 described later. Here, when the operation of the MAXBET button 8 is valid, the sub-control board 400 performs a process of emitting a later-described MAXBET button LED 721 via the MAXBET button LED board 701 of the panel LED relay board 700. Thereby, notification that the operation of the MAXBET button 8 is effective is performed.

(Stop button LED board 702)
A stop button LED board 702 is connected to a stop button LED 722 to be described later, and is provided for performing a process of emitting light to a stop button LED 722 to be described later. Here, the sub-control board 400 performs a process of emitting a stop button LED 722 to be described later via the stop button LED board 702 of the panel LED relay board 700. Specifically, when the operation of the left stop button 11 is valid, the sub-control board 400 provides a stop button LED 722 (described later) provided inside the left stop button 11 via the stop button LED board 702. When the operation of the middle stop button 12 is effective, a later-described stop button LED 722 provided inside the middle stop button 12 is emitted via the stop button LED board 702, and the right stop button is emitted. When the operation 13 is valid, a process of emitting a later-described stop button LED 722 provided inside the right stop button 13 through the stop button LED substrate 702 is performed. Thereby, notification that the operation of the left stop button 11, the middle stop button 12, and the right stop button 13 is effective is performed.

(Production button LED board 703)
The effect button LED board 703 is connected to an effect button LED 723 described later, and is provided for performing processing of emitting an effect button LED 723 described later. Here, when the operation of the effect button 21 is valid, the sub control board 400 performs a process of emitting an effect button LED 723 described later via the effect button LED board 703 of the panel LED relay board 700. Thereby, it is notified that the operation of the effect button 21 is effective.

(Lumbar panel LED substrate 704)
A waist panel LED substrate 704 is connected to a waist panel LED 724 described later, and is provided to perform a process of emitting light from a waist panel LED 724 described later. Here, the sub-control board 400 performs a process of emitting a below-described waist panel LED 724 via the waist panel LED board 704 of the panel LED relay board 700. This makes it easy for the player to recognize the model name, motif, and the like of the gaming machine 1 drawn on the waist panel 36.

(Bonus display LED substrate 705)
The Bonus display LED substrate 705 is connected to the Bonus display unit 32 and is provided for performing a process of emitting light from the LED provided in the Bonus display unit 32. Here, the sub control board 400 is provided in the Bonus display unit 32 via the Bonus display LED board 705 of the panel LED relay board 700 at the timing when the state managed by the main control board 300 shifts to the BB state. A process of emitting light from the LED is performed. Thereby, it notifies that it changed to the below-mentioned BB state.

(ART display LED substrate 706)
The ART display LED substrate 706 is connected to the ART display unit 33, and is provided for performing a process of emitting light from the LED provided in the ART display unit 33. Here, the sub control board 400 is provided in the ART display unit 33 via the ART display LED board 706 of the panel LED relay board 700 at a timing when the state managed by the main control board 300 shifts to the ART state. A process of emitting light from the LED is performed. Thereby, it notifies that it changed to the below-mentioned ART state.

(Stop button operation LED board 707)
The stop button operation LED board 707 is connected to the stop button operation display unit 34 and is provided for performing a process of emitting light from the LED provided in the stop button operation display unit 34. Here, the sub control board 400 performs a process of emitting light emitted from the LED provided in the stop button operation display unit 34 via the stop button operation LED board 707 of the panel LED relay board 700. Specifically, when the state managed by the main control board 300 is an ART state to be described later, the sub control board 400 displays the panel LED when it is the optimal timing to operate the left stop button 11. If it is the optimal timing to light the LED provided on the left stop button operation display section 34L and operate the middle stop button 12 via the stop button operation LED board 707 of the relay board 700, the control panel When it is the optimal timing to turn on the LED provided on the middle stop button operation display part 34C and operate the right stop button 13 via the stop button operation LED board 707 of the LED relay board 700, Via the stop button operation LED board 707 of the panel LED relay board 700, the right stop button operation display part 34R It performs processing for lighting the provided LED. Thereby, the optimal operation order of the left stop button 11, the middle stop button 12, and the right stop button 13 is notified.

(Start lever LED board 708)
The start lever LED substrate 708 is connected to the start lever LED 35 and is provided for performing a process of emitting light from the start lever LED 35. Here, the sub control board 400 performs a process of emitting light from the start lever LED 35 at a predetermined timing via the start lever LED board 708 of the panel LED relay board 700. Thereby, an effect appealing visually to the player is performed.

(Production button sensor 709s)
The effect button sensor 709 s is connected to the effect button 21 and is provided to detect an operation of the effect button 21. Here, the effect button sensor 709 s transmits a predetermined signal to the sub control board 400 based on the detection of the operation of the effect button 21. Then, the sub-control board 400 performs processing when the effect button 21 is operated based on the reception of the predetermined signal.

(Cross key board 710)
The cross key board 710 is connected to the cross key 22 and is provided to detect the operation of the cross key 22. Here, the cross key board 710 transmits a predetermined signal to the sub-control board 400 based on the detection of the operation of the cross key 22. Then, the sub control board 400 performs processing when the cross key 22 is operated based on the reception of the predetermined signal.

(MAX BET button LED721)
The MAXBET button LED 721 is provided inside the MAXBET button 8 and is connected to the MAXBET button LED board 701. Here, the MAXBET button LED 721 is turned on when it is time to accept the operation of the MAXBET button 8, and is turned off when it is time to accept the operation of the MAXBET button 8. Thereby, it is notified that it is the timing to accept the operation of the MAXBET button 8 and the timing to accept the operation of the MAXBET button 8.

(Stop button LED722)
The stop button LED 722 includes (a) a left stop button LED provided in the left stop button 11, (b) a middle stop button LED provided in the middle stop button 12, and (c) a right stop. A right stop button LED provided inside the button 13 is provided. Here, the left stop button LED is provided to notify that it is time to accept the operation of the left stop button 11, and the middle stop button LED is time to accept the operation of the middle stop button 12. The right stop button LED is provided to notify that it is time to accept the operation of the right stop button 13. Specifically, the left stop button LED, middle stop button LED, and right stop button LED are lit when it is time to accept the operation of the left stop button 11, the middle stop button 12, and the right stop button 13, and the left stop button is turned on. When it is time to not accept the operation of the button 11, the middle stop button 12, and the right stop button 13, the light is turned off. Accordingly, (a) it is time to accept operations of the left stop button 11, the middle stop button 12, and the right stop button 13, and (b) operations of the left stop button 11, the middle stop button 12, and the right stop button 13 are performed. Notification is made that it is a timing not to accept.

(Direction button LED723)
The effect button LED 723 is provided to notify that it is time to accept the operation of the effect button 21. Specifically, the effect button LED 723 is turned on when it is time to accept the operation of the effect button 21, and is turned off when it is time to not accept the operation of the effect button 21. Thereby, (a) it is the timing which receives operation of the production button 21, and (b) it is alert | reported that it is timing which does not receive operation of the production button 21. FIG.

(Lumbar panel LED724)
The waist panel LED 724 is provided to make it easier for the player to recognize the model name, motif, and the like of the gaming machine 1 drawn on the waist panel 36. Here, the waist panel LED 724 is lit when power is supplied to the gaming machine 1. This makes it easier for the player to recognize the model name, motif, etc. of the gaming machine 1 drawn on the waist panel 36. Note that the lumbar panel LED 724 may be turned off based on the fact that a predetermined condition has been satisfied. Thereby, it can be notified to the player that a predetermined condition has been satisfied.

(Array data table)
Next, the array data table will be described with reference to FIG.

  The arrangement data table is provided in the main ROM 302, and the symbol position of the symbol displayed in the middle of the display window 23 when the left reel sensor 154s, the middle reel sensor 155s, and the right reel sensor 156s detect the reel index. Is defined as “00”. Also, symbol positions “00” to “20” are defined based on the symbol position “00”.

(The symbol combination table whose symbol combination group is “00”)
Next, a symbol combination table whose symbol combination group is “00” will be described with reference to FIG.

  The symbol combination table whose symbol combination group is “00” is stored in the payout ROM 352 and includes a symbol combination name, a bit corresponding to the symbol combination name, a symbol bit name corresponding to the bit, and a symbol combination. The number of medals to be paid out to the player is defined.

  In addition, in the symbol “000001” of the symbol combination table with the symbol combination group “00”, “same color red BB” is defined as the symbol bit name “BNS01”, and the symbol “00000010” has the symbol bit name “000”. “BNS02” is defined as “same color blue BB”, bit “00000100” is defined as symbol bit name “BNS03”, “different color red BB” is defined, and bit “00001000” is defined as symbol bit name “ “Unusual blue BB” is defined as “BNS04”, and “JAC” is defined as the symbol bit name “BNS05” in the bit “00010000”.

  Here, when the symbol combination displayed along the active line matches the symbol combination specified in the symbol combination table, the medal payout, the re-game operation, the bonus operation, the gaming state Control which grants the privilege of transfer is performed. For example, when the symbol combination of “Red Seven”, “Red Seven”, and “Red Seven” is displayed on the active line, it is determined that the symbol combination related to “same color red BB” is displayed, and the bonus is activated. And a control for shifting to the second RT gaming state during BB, which will be described later, is performed. Note that if the symbol combination displayed along the active line does not match the symbol combination defined in the symbol combination table, it is “lost”.

  In this embodiment, when a combination of symbols related to “same color red BB”, “same color blue BB”, “different color red BB”, and “different color blue BB” is displayed on the effective line, If the operation of the accessory continuous operation device relating to the one kind of special accessory is performed and the operation of the BB is performed, the winning probability of the RB is improved. Further, in the present embodiment, when the combination of symbols related to “JAC” is displayed on the active line, the operation of RB (first type special object) is performed, and the operation of RB is performed. The winning probability of “push order bell A”, “push order bell B”, “push order bell C”, “push order bell D”, and “push order bell E”, which will be described later, is improved.

  In this embodiment, “a combination of symbols related to the same color red BB”, “a combination of symbols related to the same color blue BB”, “a combination of symbols related to the different color red BB”, “a combination of symbols related to the different color blue BB”. Are collectively referred to as “a combination of symbols related to BB”. Further, “a combination of symbols related to the same color red BB” and “a combination of symbols related to the same color blue BB” are collectively referred to as “a combination of symbols related to the same color BB”. Further, “a combination of symbols related to different color red BB” and “a combination of symbols related to different color blue BB” are collectively referred to as “a combination of symbols related to different color BB”.

  In the present embodiment, “a combination of symbols related to the same color red BB”, “a combination of symbols related to the same color blue BB”, “a combination of symbols related to the different color red BB”, “a combination of symbols related to the different color blue BB”. The “combination of symbols related to JAC” is collectively referred to as “combination of symbols related to bonus”.

(The symbol combination table whose symbol combination group is “01”)
Next, the symbol combination table whose symbol combination group is “01” will be described with reference to FIG.

  The symbol combination table with the symbol combination group “01” is stored in the payout ROM 352 in the same manner as the symbol combination table with the symbol combination group “00”. The symbol combination name, the bit corresponding to the symbol combination name, The symbol name corresponding to the bit, the combination of symbols, and the number of medals to be paid out to the player are defined.

  In addition, “general replay” is defined as the symbol bit name “REP01” in the bit “00000001” of the symbol combination table whose symbol combination group is “01”, and the symbol bit name “REP02” is included in the bit “00000010”. ”Is defined as“ first RT gaming state transition replay ”, bit“ 00000100 ”is defined as symbol bit name“ REP03 ”as“ third RT gaming state transition replay ”, and bit“ 00001000 ”is defined as bit“ 00001000 ”. , “4th RT gaming state transition replay” is defined as the symbol bit name “REP04”, “first watermelon play” is defined as the symbol bit name “REP05” in the bit “00010000”, and the bit “ In “00100000”, the design bit name “REP” “2” is defined as “6”, “first BAR replay” is defined as the symbol bit name “REP07” in the bit “01000000”, and symbol bit name is defined in the bit “10000000”. “Second BAR replay” is defined as “REP08”.

  Here, in the present embodiment, “general replay”, “first RT gaming state transition replay”, “third RT gaming state transition replay”, “fourth RT gaming state transition replay”, “first watermelon play”, “first When a combination of symbols related to “2 watermelon play”, “first BAR replay”, and “second BAR replay” is displayed on the active line, the replay is activated. When the re-game operation is performed, the game can be performed without inserting medals.

  In this embodiment, “a combination of symbols related to the general replay”, “a combination of symbols related to the first RT gaming state transition replay”, “a combination of symbols related to the third RT gaming state transition replay”, “fourth RT gaming state” “Combination of symbols related to transition replay”, “Combination of symbols related to first watermelon play”, “Combination of symbols related to second watermelon play”, “Combination of symbols related to first BAR replay”, “Combination of second BAR replay” “Combination of symbols” is collectively referred to as “combination of symbols related to replay”.

  In the present embodiment, “first RT gaming state transition replay”, “third RT gaming state transition replay”, and “fourth RT gaming state transition replay” are collectively referred to as “RT gaming state transition replay”. In addition, “the combination of symbols related to the first RT gaming state transition replay”, “the combination of symbols related to the third RT gaming state transition replay” and “the combination of symbols related to the fourth RT gaming state transition replay” are collectively referred to as “RT This is referred to as a “combination of symbols relating to a game state transition replay”.

  In the present embodiment, “first watermelon play” and “second watermelon play” are collectively referred to as “watermelon play”. Further, “the combination of symbols related to the first watermelon play” and “the combination of symbols related to the second watermelon play” are collectively referred to as “the combination of symbols related to the watermelon play”.

  In the present embodiment, “first BAR replay” and “second BAR replay” are collectively referred to as “BAR replay”. Further, “the combination of symbols related to the first BAR replay” and “the combination of symbols related to the second BAR replay” are collectively referred to as “the combination of symbols related to the BAR replay”.

(The symbol combination table whose symbol combination group is “02”)
Next, the symbol combination table whose symbol combination group is “02” will be described with reference to FIG.

  The symbol combination table with the symbol combination group “02” is stored in the payout ROM 352 in the same manner as the symbol combination table with the symbol combination group “00” and the symbol combination table with the symbol combination group “01”. The combination name, the bit corresponding to the symbol combination name, the symbol bit name corresponding to the bit, the symbol combination, and the number of medals to be paid out to the player are defined. Note that “ANY” defined in the symbol combination table whose symbol combination group is “02” indicates that any symbol may be used.

  In addition, in the symbol combination table bit “00000001” in which the symbol combination group is “02”, “first small role” is defined as symbol bit name “NML01”, and symbol “00000010” has symbol bit name. “NML02” defines “second small role”, bit “00000100” defines symbol bit name “NML03”, “third small role”, and bit “00001000” includes symbol As the bit name “NML04”, “fourth small role” is defined.

  Here, in the present embodiment, when a combination of symbols relating to “first small role”, “second small role”, “third small role”, and “fourth small role” is displayed on the active line In addition, medals are paid out.

  The “first small role”, “second small role”, “third small role”, and “fourth small role” are collectively referred to as “small role”. In addition, “Combination of symbols related to the first small role”, “Combination of symbols related to the second small role”, “Combination of symbols related to the third small role”, and “Combination of symbols related to the fourth small role” Collectively, it is called “a combination of symbols related to winning a prize”.

  Here, in this embodiment, “a combination of symbols related to winning” may be displayed on a plurality of active lines. For example, when a symbol related to “bell” is displayed in the middle stage of the middle reel 19, “downward right line”, “middle stage line”, “upward right line”, “Oyama line”, and “small V line” are “ "Combination of symbols related to the first small role" will be displayed. In this case, the number of medals obtained by multiplying the number of active lines on which the symbol combination related to winning is displayed by the number of medals paid out is paid out to the player.

(Relationship between winning role, stop button operation order, winnings etc.)
Next, based on FIG. 9, the relationship between the winning combination, the operation sequence of the stop button, and winnings will be described.

  In FIG. 9, the winning number corresponding to the winning combination, the contents of the winning number, the condition device corresponding to the winning combination, whether or not each game state can be determined as the winning combination, and the stop operation order are on the active line. The relationship with the combination of the symbols which can be displayed is shown.

  Further, as shown in FIG. 9, the condition device to be operated varies depending on the determined winning combination. For example, when the winning combination of the winning number “13” is determined by the internal lottery process described later, the conditional devices that are activated are “REP01”, “REP05”, and “REP07”. That is, when the winning combination of the winning number “13” is determined, “a combination of symbols related to the general replay”, “a combination of symbols related to the first watermelon play”, and “a combination of symbols related to the first BAR replay”. It is allowed to be displayed on the active line.

  In this embodiment, even if the left stop button 11, the middle stop button 12, and the right stop button 13 are operated at the same symbol position, the player operates the left stop button 11, the middle stop button 12, and the right stop button 13. Depending on the order, winning combinations with different combinations of symbols on the active line are provided. For example, when “RT3 replay A” with a winning number “03” is determined as a winning combination by an internal lottery process to be described later, the conditional devices that are activated are “REP01” and “REP04”. In this case, when the left stop button 11 is operated for the first time, the “combination of symbols related to general replay” is displayed on the active line. In addition, when the middle stop button 12 is operated first or when the right stop button 13 is operated first, a combination of symbols related to “the fourth RT gaming state transition replay” is displayed on the active line. Become.

  Further, in the present embodiment, the winning combination in which “the combination of symbols related to winning” is aligned depends on the operation order of the left stop button 11, the middle stop button 12, and the right stop button 13 by the player. Is provided. For example, when the “push order bell A” of the winning number “21” is determined as a winning combination by an internal lottery process to be described later, the condition device that is activated is “NML01”. In this case, when the left stop button 11 is first operated, then the middle stop button 12 is operated, and the right stop button 13 is operated last, the “combination of symbols relating to the first small role” is “ It is displayed on the “downwardly right line”, “middle line”, “upward right line”, “Oyama line”, and “small V line”. On the other hand, when the left stop button 11, the middle stop button 12, and the right stop button 13 are operated in another order, the “combination of symbols relating to the first small part” is displayed only on the “upper line”. Become.

  Similarly, when the “push order bell B” of the winning number “22” is determined as the winning combination by the internal lottery process described later, the left stop button 11 is operated first, and then the right stop button 13 is operated. Finally, when the middle stop button 12 is operated, the “combination of symbols relating to the first small role” is “right-down line”, “middle line”, “right-up line”, “Oyama line”, and It is displayed on the “small V line”. On the other hand, when the left stop button 11, the middle stop button 12, and the right stop button 13 are operated in another order, the “combination of symbols relating to the first small part” is displayed only on the “upper line”. Become.

  Further, when the “push order bell C” of the winning number “23” is determined as the winning combination by the internal lottery process described later, when the middle stop button 12 is operated for the first time, Such symbol combinations ”are displayed on the“ lower right line ”,“ middle line ”,“ up right line ”,“ Oyama line ”, and“ small V line ”. On the other hand, when the left stop button 11 or the right stop button 13 is first operated, the “combination of symbols relating to the first small role” is displayed only on the “upper line”.

  Further, when the “push order bell D” of the winning number “24” is determined as the winning combination by the internal lottery process described later, the right stop button 13 is operated first, and then the left stop button 11 is operated. Finally, when the middle stop button 12 is operated, the “combination of symbols related to the first small role” is “right-down line”, “middle line”, “right-up line”, “Oyama line”, and “ It will be displayed on the “small V line”. On the other hand, when the left stop button 11, the middle stop button 12, and the right stop button 13 are operated in another order, the “combination of symbols relating to the first small part” is displayed only on the “upper line”. Become.

  Further, when “push order bell E” of the winning number “25” is determined as the winning combination by the internal lottery process described later, the right stop button 13 is operated first, and then the middle stop button 12 is operated. Finally, when the left stop button 11 is operated, the “combination of symbols relating to the first small role” is “Right-down line”, “Middle line”, “Right-up line”, “Oyama line”, and “ It will be displayed on the “small V line”. On the other hand, when the left stop button 11, the middle stop button 12, and the right stop button 13 are operated in another order, the “combination of symbols relating to the first small part” is displayed only on the “upper line”. Become.

  On the other hand, a winning combination is provided in which the combination of symbols arranged on the active line does not differ regardless of the order of operation of the left stop button 11, the middle stop button 12, and the right stop button 13. For example, when “RB” of the winning number “48” is determined as the winning combination by the internal lottery process described later, the condition device that is activated is “BNS05”. In this case, regardless of the order in which the left stop button 11, the middle stop button 12, and the right stop button 13 are operated, the “combination of symbols related to JAC” is displayed on the active line. It becomes.

(Non-RT gaming state winning combination determination table)
Next, the winning combination determination table for non-RT gaming state will be described with reference to FIG.

  The non-RT gaming state winning combination determination table is stored in the main ROM 302 and is used when determining a winning combination by an internal lottery process described later in a non-RT gaming state described later.

  Further, the winning combination determination table for non-RT gaming state defines a winning number, contents of the winning number, and a lottery value for each set value. Here, in this embodiment, the winning combination determination table for the non-RT gaming state includes a lottery value when the setting value is “1”, a lottery value when the setting value is “2”, and a setting value of “3”. ”, Lottery value when the setting value is“ 4 ”, lottery value when the setting value is“ 5 ”, and lottery value when the setting value is“ 6 ”. Yes. In FIG. 10, the lottery value when the set value is “2”, the lottery value when the set value is “3”, the lottery value when the set value is “4”, and the set value is “5”. Illustration of lottery values in this case is omitted.

  In addition, the winning combination determination table for the non-RT gaming state includes a “normal replay” with a winning number “01”, a “direct replay” with a winning number “18”, a “successful play” with a winning number “19”, “Chance Replay” with the number “20”, “Push Order Bell A” with the winning number “21”, “Push Order Bell B” with the winning number “22”, and “Push Order Bell C” with the winning number “23”. ”,“ Push Order Bell D ”with a winning number“ 24 ”,“ Push Order Bell E ”with a winning number“ 25 ”,“ Cherry ”with a winning number“ 26 ”, and“ Red ”with a winning number“ 28 ”. “Seven BB”, “Blue Seven BB” with a winning number “29”, “Different Red Seven BB” with a winning number “30”, “Unique Blue Seven BB” with a winning number “31”, and a winning number “32” "Chance Replay + Red Seven BB" and the winning number "33" “Sleep Play + Blue Seven BB”, “Chance Replay + Different Color Red Seven BB” with the winning number “34”, “Chance Replay + Different Color Blue Seven BB” with the winning number “35” and “Watermelon” with the winning number “36” "Replay + Red Seven BB", Winning Number "37" Watermelon Play + Blue Seven BB, Winning Number "38" "Watermelon Play + Different Color Red Seven BB", Winning Number "39" "Watermelon Play" + Different color blue seven BB, winning number “40” cherry + red seven BB, winning number “41” cherry + blue seven BB, and winning number “42” “cherry + different color red seven” BB ”, winning number“ 43 ”“ cherry + different color blue seven BB ”, winning number“ 44 ”“ middle stage cherry + red seven BB ”, and winning number“ 45 ”“ middle stage cherry + blue series ” And emissions BB ", the" middle Cherry + different color red Seven BB "winning numbers" 46 ", lottery value to the" middle Cherry + unique blue seven BB "of the winning number" 47 "are defined.

  That is, the lottery value other than these is “0”, and when the lottery is performed using the winning combination determination table for the non-RT gaming state, the “replay during RT2” of the winning number “02” and the winning number “03” “Replay A during RT3”, “Replay B during RT3” with winning number “04”, “Replay C during RT3” with winning number “05”, “Replay A during RT4” with winning number “06”, Winning number “Replay B during RT4” of “07”, “Replay C during RT4” of winning number “08”, “Replay D during RT4” of winning number “09”, “Replay E during RT4” of winning number “10”, Winning number “11” “RT4 replay F”, winning number “12” “BAR-matched replay S1”, winning number “13” “BAR-matched replay S2”, winning number “14” “BAR-matched replay S3” " “BAR-matched replay W1” with a selection number “15”, “BAR-matched replay W2” with a winning number “16”, “BAR-matched replay W3” with a winning number “17”, “middle cherries” with a winning number “27”, The winning number “48” “RB” is not determined as the winning combination.

(First RT gaming state winning combination determination table)
Next, the winning combination determination table for the first RT gaming state will be described based on FIG.

  The first RT gaming state winning combination determination table is stored in the main ROM 302 and is used when determining a winning combination by an internal lottery process described later in the first RT gaming state described later.

  In the first RT gaming state winning combination determination table, a winning number, contents of the winning number, and a lottery value for each set value are defined. Here, in the present embodiment, the first RT gaming state winning combination determination table includes a lottery value when the setting value is “1”, a lottery value when the setting value is “2”, and a setting value of “3”. ”, Lottery value when the setting value is“ 4 ”, lottery value when the setting value is“ 5 ”, and lottery value when the setting value is“ 6 ”. Yes. In FIG. 11, the lottery value when the set value is “2”, the lottery value when the set value is “3”, the lottery value when the set value is “4”, and the set value is “5”. Illustration of lottery values in this case is omitted.

  In addition, the winning combination determination table for the first RT gaming state includes a “normal replay” with a winning number “01”, a “direct replay” with a winning number “18”, a “watermelon play” with a winning number “19”, and a winning combination. “Chance Replay” with the number “20”, “Push Order Bell A” with the winning number “21”, “Push Order Bell B” with the winning number “22”, and “Push Order Bell C” with the winning number “23”. ”,“ Push Order Bell D ”with a winning number“ 24 ”,“ Push Order Bell E ”with a winning number“ 25 ”,“ Cherry ”with a winning number“ 26 ”, and“ Red ”with a winning number“ 28 ”. “Seven BB”, “Blue Seven BB” with a winning number “29”, “Different Red Seven BB” with a winning number “30”, “Unique Blue Seven BB” with a winning number “31”, and a winning number “32” "Chance Replay + Red Seven BB" and the winning number "33" "Sleep Play + Blue Seven BB", "Chance Replay + Different Color Red Seven BB" with the winning number "34", "Chance Replay + Different Color Blue Seven BB" with the winning number "35", and " "Watermelon Play + Red Seven BB", Winning Number "37" Watermelon Play + Blue Seven BB, Winning Number "38" "Watermelon Play + Different Color Red Seven BB", Winning Number "39" "Watermelon "Replay + Different Color Blue Seven BB", Winning Number "40" "Cherry + Red Seven BB", Winning Number "41" "Cherry + Blue Seven BB" and Winning Number "42" "Cherry + Different Color Red" "Seven BB", winning number "43" "cherry + different color blue seven BB", winning number "44" "middle cherry + red seven BB", winning number "45" "middle cherry + blue" And minutes BB ", the" middle Cherry + different color red Seven BB "winning numbers" 46 ", lottery value to the" middle Cherry + unique blue seven BB "of the winning number" 47 "are defined.

  That is, the lottery value other than these is “0”, and when the lottery is performed using the winning combination determination table for the first RT gaming state, the “replay during RT2” of the winning number “02” and the winning number “03” “Replay A during RT3”, “Replay B during RT3” with winning number “04”, “Replay C during RT3” with winning number “05”, “Replay A during RT4” with winning number “06”, Winning number “Replay B during RT4” of “07”, “Replay C during RT4” of winning number “08”, “Replay D during RT4” of winning number “09”, “Replay E during RT4” of winning number “10”, Winning number “11” “RT4 replay F”, winning number “12” “BAR-matched replay S1”, winning number “13” “BAR-matched replay S2”, winning number “14” “BAR-matched replay S3” " “BAR-matched replay W1” with a winning number “15”, “BAR-matched replay W2” with a winning number “16”, “BAR-matched replay W3” with a winning number “17”, “middle cherries” with a winning number “27”, The winning number “48” “RB” is not determined as the winning combination.

(Winning role determination table for 2nd RT gaming state during BB)
Next, the winning combination determination table for the second RT gaming state during BB will be described based on FIG.

  The BB second RT gaming state winning combination determination table is stored in the main ROM 302, and is used when determining a winning combination by an internal lottery process described later in the BB second RT gaming state described later.

  In the BB second RT gaming state winning combination determination table, a winning number, contents of the winning number, and a lottery value for each set value are defined. Here, in the present embodiment, in the BB second RT gaming state winning combination determination table, the lottery value when the setting value is “1”, the lottery value when the setting value is “2”, and the setting value are The lottery value when “3”, the lottery value when the setting value is “4”, the lottery value when the setting value is “5”, and the lottery value when the setting value is “6” are defined respectively. Has been. In FIG. 12, the lottery value when the setting value is “2”, the lottery value when the setting value is “3”, the lottery value when the setting value is “4”, and the setting value is “5”. Illustration of lottery values in this case is omitted.

  In addition, the winning combination determination table for the second RT gaming state during the BB includes “normal replay” of the winning number “01”, “replaying during RT2” of the winning number “02”, and “watermelon play” of the winning number “19”. “Chance Replay” with the winning number “20”, “Push Order Bell A” with the winning number “21”, “Push Order Bell B” with the winning number “22”, and “Pushing with the winning number“ 23 ”. "Sequence Bell C", "Push Order Bell D" with a winning number "24", "Push Order Bell E" with a winning number "25", "Cherry" with a winning number "26", and a winning number "27" Lottery values are defined for “middle stage cherry” and “RB” of the winning number “48”.

  That is, the lottery value other than these is “0”, and when the lottery is performed using the winning combination determination table for the second RT gaming state during BB, “Replay A during RT3” with the winning number “03” “Replay B during RT3” with the number “04”, “Replay C during RT3” with the winning number “05”, “Replay A during RT4” with the winning number “06”, “Replay B during RT4” with the winning number “07” “Replay C during RT4” with winning number “08”, “Replay D during RT4” with winning number “09”, “Replay during RT4” with winning number “10”, “Replay during RT4” with winning number “11” "F", "BAR-matched replay S1" with winning number "12", "BAR-matched replay S2" with winning number "13", "BAR-matched replay S3" with winning number "14", "BAR" with winning number "15" Complete "Ray W1", "BAR-matched replay W2" with winning number "16", "BAR-matched replay W3" with winning number "17", "Direct hit replay" with winning number "18", "Red Seven" with winning number "28" BB, winning number “29” “Blue Seven BB”, winning number “30” “Different Red Seven BB”, winning number “31” “Different Blue Seven BB”, winning number “32” “Chance Replay” + Red Seven BB ”, Winning Number“ 33 ”“ Chance Replay + Blue Seven BB ”, Winning Number“ 34 ”“ Chance Replay + Different Color Red Seven BB ”, Winning Number“ 35 ”“ Chance Replay + Different Color Blue Seven ” "BB", winning number "36" "Watermelon Play + Red Seven BB", winning number "37" "Watermelon Play + Blue Seven BB", winning number "38" "BB", winning number "39" "Watermelon Play + Different Color Blue Seven BB", winning number "40" "Cherry + Red Seven BB", winning number "41" "Cherry + Blue Seven BB", winning number “42” “Cherry + Different Color Red Seven BB”, Winning Number “43” “Cherry + Different Color Blue Seven BB”, Winning Number “44” “Medium Stage Cherry + Red Seven BB”, Winning Number “45” “ “Middle stage cherry + blue seven BB”, “Middle stage cherry + different color red seven BB” with the winning number “46”, and “Middle stage cherry + different color blue seven BB” with the winning number “47” will not be determined as the winning combination.

(Winning combination determination table for second RT gaming state during non-BB)
Next, based on FIG. 13, the winning combination determination table for the non-BB second RT gaming state will be described.

  The non-BB second RT gaming state winning combination determination table is stored in the main ROM 302 and is used when determining a winning combination by an internal lottery process described later in the non-BB second RT gaming state described later.

  Further, in the non-BB second RT gaming state winning combination determination table, a winning number, contents of the winning number, and a lottery value for each set value are defined. Here, in the present embodiment, the winning combination determination table for the non-BB second RT gaming state includes a lottery value when the setting value is “1”, a lottery value when the setting value is “2”, and a setting value. The lottery value when “3” is set, the lottery value when the setting value is “4”, the lottery value when the setting value is “5”, and the lottery value when the setting value is “6”, respectively. It is prescribed. In FIG. 13, the lottery value when the setting value is “2”, the lottery value when the setting value is “3”, the lottery value when the setting value is “4”, and the setting value is “5”. Illustration of lottery values in this case is omitted.

  In addition, the winning combination determination table for the second RT gaming state during the non-BB includes “normal replay” of the winning number “01”, “replaying during RT2” of the winning number “02”, and “watermelon play of the winning number“ 19 ”. ”,“ Chance Replay ”with a winning number“ 20 ”,“ Push Order Bell A ”with a winning number“ 21 ”,“ Push Order Bell B ”with a winning number“ 22 ”, and“ “Push Order Bell C”, “Push Order Bell D” of Winning Number “24”, “Push Order Bell E” of Winning Number “25”, “Cherry” of Winning Number “26”, and Winning Number “28” "Red Seven BB", winning number "29" "Blue Seven BB", winning number "30" "Different Red Seven BB", winning number "31" "Different Blue Seven BB" Winning number “32” “Chance Replay + Red Seven BB” and winning number “ “Chance Replay + Blue Seven BB” of “3”, “Chance Replay + Different Color Red Seven BB” of the winning number “34”, “Chance Replay + Different Color Blue Seven BB” of the winning number “35” and the winning number “ 36 ”“ Watermelon Play + Red Seven BB ”, Winning Number“ 37 ”“ Watermelon Play + Blue Seven BB ”, Winning Number“ 38 ”“ Watermelon Play + Different Color Red Seven BB ”and Winning Number“ 39 ” "Watermelon Play + Different Color Blue Seven BB", "Cherry + Red Seven BB" with the winning number "40", "Cherry + Blue Seven BB" with the winning number "41" and "42" with the winning number "42" “Cherry + Different Color Red Seven BB”, “Cherry + Different Color Blue Seven BB” with the winning number “43”, “Middle Cherry + Red Seven BB” with the winning number “44”, “Center” with the winning number “45” Ferry + and blue seven BB ", the" middle Cherry + different color red Seven BB "winning numbers" 46 ", lottery value to the" middle Cherry + unique blue seven BB "of the winning number" 47 "are defined.

  That is, the lottery value other than these is “0”, and when the lottery is performed using the winning combination determination table for the second RT gaming state during the non-BB, the winning number “03” “RT3 replay A”, Winning number “04” “RT3 replay B”, winning number “05” “RT3 replay C”, winning number “06” “RT4 replay A”, winning number “07” “RT4 replay B” "Replay C during RT4" with winning number "08", "Replay D during RT4" with winning number "09", "Replay E during RT4" with winning number "10", "In RT4 with winning number" 11 " "Replay F", "BAR-matched replay S1" with winning number "12", "BAR-matched replay S2" with winning number "13", "BAR-matched replay S3" with winning number "14", "" BAR set “Play W1”, “BAR-matched replay W2” with a winning number “16”, “BAR-matched replay W3” with a winning number “17”, “Direct replay” with a winning number “18”, “Medium stage cherry” with a winning number “27” “RB” of the winning number “48” is not determined as the winning combination.

(Winning role determination table for 3rd RT gaming state during BB)
Next, the winning combination determination table for the third RT gaming state during BB will be described based on FIG.

  The BB third RT gaming state winning combination determination table is stored in the main ROM 302, and is used when a winning combination is determined by an internal lottery process described later in the BB third RT gaming state described later.

  In the BB third RT gaming state winning combination determination table, a winning number, contents of the winning number, and a lottery value for each set value are defined. Here, in the present embodiment, the winning combination determination table for the third RT gaming state during BB includes a lottery value when the setting value is “1”, a lottery value when the setting value is “2”, and the setting value. The lottery value when “3”, the lottery value when the setting value is “4”, the lottery value when the setting value is “5”, and the lottery value when the setting value is “6” are defined respectively. Has been. In FIG. 14, the lottery value when the set value is “2”, the lottery value when the set value is “3”, the lottery value when the set value is “4”, and the set value is “5”. Illustration of lottery values in this case is omitted.

  In addition, the winning combination determination table for the third RT gaming state during the BB includes “normal replay” of the winning number “01”, “replaying during RT3” of the winning number “03”, and “in RT3 of the winning number“ 04 ”. “Replay B”, “Replay C in RT3” with a winning number “05”, “Watermelon play” with a winning number “19”, “Chance Replay” with a winning number “20”, and “21” with a winning number “21”. “Push Order Bell A”, “Push Order Bell B” of Winning Number “22”, “Push Order Bell C” of Winning Number “23”, “Push Order Bell D” of Winning Number “24”, Winning Lottery values are defined for “push order bell E” of number “25”, “cherry” of winning number “26”, and “middle stage cherry” of winning number “27”.

  That is, the lottery value other than these is “0”, and when the lottery is performed using the winning combination determination table for the third RT gaming state during BB, “Replay during RT2” with the winning number “02”, the winning number “Replay A during RT4” of “06”, “Replay B during RT4” of winning number “07”, “Replay C during RT4” of winning number “08”, “Replay D during RT4” of winning number “09”, Winning number “10” “RT4 replay E”, winning number “11” “RT4 replay F”, winning number “12” “BAR-matched replay S1”, winning number “13” “BAR-matched replay S2” "," BAR-matched replay S3 "with a winning number" 14 "," BAR-matched replay W1 "with a winning number" 15 "," BAR-matched replay W2 "with a winning number" 16 "," BAR "with a winning number" 17 " "Replay W3", "Direct Replay" with winning number "18", "Red Seven BB" with winning number "28", "Blue Seven BB" with winning number "29", "Different Red Seven" with winning number "30" "BB", "Different Blue Seven BB" with winning number "31", "Chance Replay + Red Seven BB" with winning number "32", "Chance Replay + Blue Seven BB" with winning number "33", Winning number "34" "Chance Replay + Different Color Red Seven BB", Winning Number "35" "Chance Replay + Different Color Blue Seven BB", Winning Number "36" "Watermelon Play + Red Seven BB", Winning Number "37" "Suikari Play + Blue Seven BB", Winning Number "38" "Watermelon Play + Different Color Red Seven BB", Winning Number "39" "Watermelon Play + Different Color Blue Seven BB", Winning Number "40" "Cherry + Red Seven BB", Winning Number "41" "Cherry + Blue Seven BB", Winning Number "42" "Cherry + Different Color Red Seven BB", Winning Number "43" "Cherry + Different Color Blue Seven BB" , Winning number “44” “middle cherry + red seven BB”, winning number “45” “middle cherry + blue seven BB”, winning number “46” “middle cherry + red red BB”, winning number “ “47” “middle cherry + different color blue seven BB” and “RB” of the winning number “48” are not determined as winning combinations.

(Non-BB 3rd RT gaming state winning combination determination table)
Next, the winning combination determination table for the third RT gaming state during non-BB will be described based on FIG.

  The non-BB third RT gaming state winning combination determination table is stored in the main ROM 302, and is used when determining a winning combination by an internal lottery process described later in the non-BB third RT gaming state described later.

  In the non-BB third RT gaming state winning combination determination table, a winning number, contents of the winning number, and a lottery value for each set value are defined. Here, in the present embodiment, the winning combination determination table for the non-BB third RT gaming state includes the lottery value when the setting value is “1”, the lottery value when the setting value is “2”, and the setting value. The lottery value when “3” is set, the lottery value when the setting value is “4”, the lottery value when the setting value is “5”, and the lottery value when the setting value is “6”, respectively. It is prescribed. In FIG. 15, the lottery value when the setting value is “2”, the lottery value when the setting value is “3”, the lottery value when the setting value is “4”, and the setting value is “5”. Illustration of lottery values in this case is omitted.

  In addition, the winning combination determination table for the third RT gaming state during non-BB includes “normal replay” of the winning number “01”, “replaying during RT3” of the winning number “03”, and “RT3 of the winning number“ 04 ”. “Middle Replay B”, “05 Replay C in RT3” with Winning Number “05”, “Watermelon Play” with Winning Number “19”, “Chance Replay” with Winning Number “20”, and Winning Number “21” “Push order bell A”, “push order bell B” of winning number “22”, “push order bell C” of winning number “23”, “push order bell D” of winning number “24”, Winning number “25” “Push Order Bell E”, Winning Number “26” “Cherry”, Winning Number “28” “Red Seven BB”, Winning Number “29” “Blue Seven BB” , The winning number “30” “different color red Seven BB” and the winning number “31” "Issue Blue Seven BB", "Chance Replay + Red Seven BB" with winning number "32", "Chance Replay + Blue Seven BB" with winning number "33", "Chance Replay + Different Color" with winning number "34" “Red Seven BB”, “Chance Replay + Unique Blue Seven BB” with winning number “35”, “Suikari Play + Red Seven BB” with winning number “36”, “Suikari Play + Blue” with winning number “37” "Seven BB", winning number "38" "Watermelon Play + Different Color Red Seven BB", winning number "39" "Watermelon Play + Different Color Blue Seven BB", and winning number "40" "Cherry + Red Seven" BB ”, winning number“ 41 ”“ Cherry + Blue Seven BB ”, winning number“ 42 ”“ Cherry + Different Color Red Seven BB ”, and winning number“ 43 ”“ Cherry + Different Color Blue Blue ” BB ”, winning number“ 44 ”“ middle cherry + red seven BB ”, winning number“ 45 ”“ middle cherry + blue seven BB ”and winning number“ 46 ”“ middle cherry + different color red seven ” The lottery values are defined for “BB” and the winning number “47” “middle cherry + different color blue seven BB”.

  In other words, the lottery value other than these is “0”, and when the lottery is performed using the winning combination determination table for the third RT gaming state in the non-BB, the winning number “02” “Replay during RT2”, winning “Replay A during RT4” with number “06”, “Replay B during RT4” with winning number “07”, “Replay C during RT4” with winning number “08”, “Replay D during RT4” with winning number “09” The winning number “10” “RT4 replay E”, the winning number “11” “RT4 replay F”, the winning number “12” “BAR matching replay S1”, and the winning number “13” “BAR matching replay”. “S2”, “BAR-matched replay S3” with winning number “14”, “BAR-matched replay W1” with winning number “15”, “BAR-matched replay W2” with winning number “16”, “BA with winning number“ 17 ” Matching replay W3 "," hit replay "of the winning number" 18 "," middle cherry "winning numbers" 27 ", will not be determined as" RB "is the winning combination of winning numbers" 48 ".

(Winning role determination table for 4th RT gaming state)
Next, based on FIG. 16, the 4RT gaming state winning combination determination table will be described.

  The fourth RT gaming state winning combination determination table is stored in the main ROM 302, and is used when determining a winning combination by an internal lottery process described later in the fourth RT gaming state described later.

  In the fourth RT gaming state winning combination determination table, a winning number, contents of the winning number, and a lottery value for each set value are defined. Here, in the present embodiment, in the fourth RT gaming state winning combination determination table, the lottery value when the set value is “1”, the lottery value when the set value is “2”, and the set value is “3”. ”, Lottery value when the setting value is“ 4 ”, lottery value when the setting value is“ 5 ”, and lottery value when the setting value is“ 6 ”. Yes. In FIG. 16, the lottery value when the setting value is “2”, the lottery value when the setting value is “3”, the lottery value when the setting value is “4”, and the setting value is “5”. Illustration of lottery values in this case is omitted.

  In addition, the winning combination determination table for the fourth RT gaming state includes “normal replay” of the winning number “01”, “replay A during RT4” of the winning number “06”, and “replay B during RT4” of the winning number “07”. "" Replay C during RT4 "with a winning number" 08 "," Replay D during RT4 "with a winning number" 09 "," Replay E during RT4 "with a winning number" 10 ", and a winning number" 11 " “Replay F in RT4”, “BAR-matched replay S1” with winning number “12”, “BAR-matched replay S2” with winning number “13”, and “BAR-matched replay S3” with winning number “14” , “BAR-matched replay W1” with a winning number “15”, “BAR-matched replay W2” with a winning number “16”, “BAR-matched replay W3” with a winning number “17”, and “19” with a winning number “19”. Watermelon "I", "Chance Replay" with winning number "20", "Push Order Bell A" with winning number "21", "Push Order Bell B" with winning number "22", and Winning Number "23" “Push Order Bell C”, “Push Order Bell D” with a winning number “24”, “Push Order Bell E” with a winning number “25”, “Cherry” with a winning number “26”, and a winning number “ “Red Seven BB” with 28, “Blue Seven BB” with winning number “29”, “Different Red Seven BB” with winning number “30”, “Different Blue Seven BB” with winning number “31” , “Chance Replay + Red Seven BB” with the winning number “32”, “Chance Replay + Blue Seven BB” with the winning number “33”, “Chance Replay + Different Color Red Seven BB” with the winning number “34”, “Chance Replay + Unique Blue Seven BB” with winning number “35” Winning number “36” “Watermelon Play + Red Seven BB”, Winning Number “37” “Watermelon Play + Blue Seven BB”, Winning Number “38” “Watermelon Play + Different Color Red Seven BB”, Winning Number 39 “Suikari Play + Different Color Blue Seven BB”, Winning Number “40” “Cherry + Red Seven BB”, Winning Number “41” “Cherry + Blue Seven BB” and Winning Number “42” "Cherry + Different Color Red Seven BB", Winning Number "43" "Cherry + Different Color Blue Seven BB", Winning Number "44" "Medium Stage Cherry + Red Seven BB" and Winning Number "45" Lottery values are defined for “middle cherry + blue seven BB”, “middle cherry + different color red seven BB” with winning number “46”, and “middle cherry + different color blue seven BB” with winning number “47”. .

  That is, the lottery value other than these is “0”, and when the lottery is performed using the winning combination determination table for the first RT gaming state, the “replay during RT2” of the winning number “02” and the winning number “03” “Replay A during RT3”, “Replay B during RT3” with winning number “04”, “Replay C during RT3” with winning number “05”, “Direct Replay” with winning number “18”, Winning number “27” "Crowd Cherry" of "" and "RB" of the winning number "48" are not determined as the winning combination.

(5th RT gaming state winning combination determination table)
Next, the winning combination determination table for the fifth RT gaming state will be described based on FIG.

  The fifth RT gaming state winning combination determination table is stored in the main ROM 302 and is used when determining a winning combination by an internal lottery process described later in the fifth RT gaming state described later.

  In the fifth RT gaming state winning combination determination table, a winning number, contents of the winning number, and a lottery value for each set value are defined. Here, in the present embodiment, the fifth RT gaming state winning combination determination table includes a lottery value when the setting value is “1”, a lottery value when the setting value is “2”, and a setting value of “3”. ”, Lottery value when the setting value is“ 4 ”, lottery value when the setting value is“ 5 ”, and lottery value when the setting value is“ 6 ”. Yes. In FIG. 17, the lottery value when the setting value is “2”, the lottery value when the setting value is “3”, the lottery value when the setting value is “4”, and the setting value is “5”. Illustration of lottery values in this case is omitted.

  In addition, the winning combination determination table for the 5th RT gaming state includes the “normal replay” with the winning number “01”, the “watermelon play” with the winning number “19”, and the “chance replay” with the winning number “20”. “Push Order Bell A” of the number “21”, “Push Order Bell B” of the winning number “22”, “Push Order Bell C” of the winning number “23”, and “Push Order of the winning number“ 24 ”. Lottery values are defined for “bell D”, “push order bell E” of winning number “25”, “cherry” of winning number “26”, and “middle stage cherry” of winning number “27”.

  That is, the lottery value other than these is “0”, and when the lottery is performed using the winning combination determination table for the 5th RT gaming state, the “replay during RT2” of the winning number “02” and the winning number “03” “Replay A during RT3”, “Replay B during RT3” with winning number “04”, “Replay C during RT3” with winning number “05”, “Replay A during RT4” with winning number “06”, Winning number “Replay B during RT4” of “07”, “Replay C during RT4” of winning number “08”, “Replay D during RT4” of winning number “09”, “Replay E during RT4” of winning number “10”, Winning number “11” “RT4 replay F”, winning number “12” “BAR-matched replay S1”, winning number “13” “BAR-matched replay S2”, winning number “14” “BAR-matched replay S3” " “BAR-matched replay W1” with a winning number “15”, “BAR-matched replay W2” with a winning number “16”, “BAR-matched replay W3” with a winning number “17”, “Direct hit replay” with a winning number “18”, “Red Seven BB” with the winning number “28”, “Blue Seven BB” with the winning number “29”, “Different Red Seven BB” with the winning number “30”, “Different Blue Seven BB” with the winning number “31”, Winning number “32” “Chance Replay + Red Seven BB”, Winning Number “33” “Chance Replay + Blue Seven BB”, Winning Number “34” “Chance Replay + Different Color Red Seven BB”, Winning Number “35” "Chance Replay + Different Color Blue Seven BB", Winning Number "36" Watermelon Play + Red Seven BB ", Winning Number" 37 "" Watermelon Play + Blue Seven BB ", Winning Number" 8 "Suikari Play + Different Color Red Seven BB", "No. 39" "Suikari Play + Different Color Blue Seven BB", "40" "Cherry + Red Seven BB", "No. 41" “Cherry + Blue Seven BB”, Winning Number “42” “Cherry + Different Color Red Seven BB”, Winning Number “43” “Cherry + Different Color Blue Seven BB”, Winning Number “44” “Medium Stage Cherry + Red Seven BB” ”, Winning number“ 45 ”“ middle cherry + blue seven BB ”, winning number“ 46 ”“ middle cherry + different color red seven BB ”, winning number“ 47 ”“ middle cherry + different color blue seven BB ”, winning The number “48” “RB” is not determined as the winning combination.

(3rd RT RB gaming status winning combination determination table)
Next, the winning combination determination table for the RB gaming state during the third RT will be described based on FIG.

  The third RT RB gaming state winning combination determination table is stored in the main ROM 302, and is used when determining the winning combination by an internal lottery process described later in the third RT RB gaming state described later.

  In the third RT RB gaming state winning combination determination table, a winning number, contents of the winning number, and a lottery value for each set value are defined. Here, in the present embodiment, in the third RT RB gaming state winning combination determination table, the lottery value when the setting value is “1”, the lottery value when the setting value is “2”, and the setting value are The lottery value when “3”, the lottery value when the setting value is “4”, the lottery value when the setting value is “5”, and the lottery value when the setting value is “6” are defined respectively. Has been. In FIG. 18, the lottery value when the setting value is “2”, the lottery value when the setting value is “3”, the lottery value when the setting value is “4”, and the setting value is “5”. Illustration of lottery values in this case is omitted.

  In addition, the winning combination determination table for the RB gaming state during the 3rd RT has “push order bell A” of the win number “21”, “push order bell B” of the win number “22”, and “ Lottery values are defined for “push order bell C”, “push order bell D” of winning number “24”, and “push order bell E” of winning number “25”.

  That is, the lottery value other than these is “0”. When the lottery is performed using the winning combination determination table for the RB gaming state during the third RT, the “normal replay” of the winning number “01” and the winning number “ “Replay during RT2” of “02”, “Replay during RT3” of winning number “03”, “Replay B during RT3” of winning number “04”, “Replay C during RT3” of winning number “05”, Winning number “Replay A during RT4” of “06”, “Replay B during RT4” of winning number “07”, “Replay C during RT4” of winning number “08”, “Replay D during RT4” of winning number “09”, Winning number “10” “RT4 replay E”, winning number “11” “RT4 replay F”, winning number “12” “BAR-matched replay S1”, winning number “13” “BAR-matched replay S2” ” “BAR-matched replay S3” with the number “14”, “BAR-matched replay W1” with the winning number “15”, “BAR-matched replay W2” with the winning number “16”, “BAR-matched replay W3” with the winning number “17” , Winning number “18” “direct hit replay”, winning number “19” “watermelon play”, winning number “20” “chance replay”, winning number “26” “cherry”, winning number “27” “Middle Cherry”, “Red Seven BB” with winning number “28”, “Blue Seven BB” with winning number “29”, “Different Red Seven BB” with winning number “30”, “Different Color” with winning number “31” “Blue Seven BB”, “Chance Replay + Red Seven BB” with winning number “32”, “Chance Replay + Blue Seven BB” with winning number “33”, “Chance Replay + different color” with winning number “34” “Seven BB”, “Chance Replay + Different Color Blue Seven BB” with winning number “35”, “Suikari Play + Red Seven BB” with winning number “36”, “Suikari Play + Blue Seven BB” with winning number “37”, Winning number “38” “Watermelon Play + Different Color Red Seven BB”, Winning Number “39” “Watermelon Play + Different Color Red Seven BB”, Winning Number “40” “Cherry + Red Seven BB”, Winning Number “41” "Cherry + Blue Seven BB", Winning Number "42" "Cherry + Different Color Red Seven BB", Winning Number "43" "Cherry + Different Color Blue Seven BB", Winning Number "44" "Red Seven BB", winning number "45" "Middle Cherry + Blue Seven BB", winning number "46" "Middle Cherry + Different Color Red Seven BB", winning number "47" "Middle Cherry" + "Issue Blue Seven BB" and "RB" with the winning number "48" are not determined as the winning combination.

  In this embodiment, “normal replay”, “replay during RT2”, “replay during RT3”, “replay during RT3”, “replay during RT3”, “replay during RT4”, “replay during RT4” “B”, “Replay during RT4”, “Replay during RT4”, “Replay during RT4”, “Replay during RT4”, “BAR replay S1”, “BAR replay S2”, “BAR replay S3” ”,“ BAR-matched replay W1 ”,“ BAR-matched replay W2 ”,“ BAR-matched replay W3 ”,“ direct hit replay ”,“ watermelon play ”, and“ chance replay ”are collectively referred to as“ replay ”.

  Further, “RT3 replay A”, “RT3 replay B”, and “RT3 replay C” are collectively referred to as “RT3 replay”. Also, “RT4 replay A”, “RT4 replay B”, “RT4 replay C”, “RT4 replay D”, “RT4 replay E”, and “RT4 replay F” are collectively referred to as “RT4 during replay F”. "Replay". Also, “BAR-matched replay S1”, “BAR-matched replay S2”, “BAR-matched replay S3”, “BAR-matched replay W1”, “BAR-matched replay W2”, and “BAR-matched replay W3” are collectively referred to as “BAR-matched replay S3”. "Replay".

  Further, “push order bell A”, “push order bell B”, “push order bell C”, “push order bell D”, and “push order bell E” are collectively referred to as “push order bell”.

  “Red Seven BB”, “Blue Seven BB”, “Different Red Seven BB”, and “Different Blue Seven BB” are collectively referred to as “BB”.

  The non-RT gaming state winning combination determination table, the first RT gaming state winning combination determining table, the BB second RT gaming state winning combination determining table, and the non-BB second RT gaming state winning combination determining table A winning combination determination table for the third RT gaming state during the BB, a winning combination determination table for the third RT gaming state during the non-BB, a winning combination determination table for the fourth RT gaming state, and a winning combination determination table for the fifth RT gaming state; The third RT RB gaming state winning combination determination table is generically referred to as a “winning combination determination table”.

(Game state transition diagram)
Next, based on FIG. 19, a gaming state transition diagram will be described.

  The game state transition diagram defines a current game state, a transition condition that is a condition for transitioning the game state, and a game state of a transition destination.

  Here, when the current gaming state is the non-RT gaming state, when “BB” is won by the internal lottery process described later, the non-RT gaming state is shifted to the fifth RT gaming state.

  In addition, when the current gaming state is a non-RT gaming state, when the “combination of symbols relating to the third RT gaming state transition replay” is displayed on the active line, the third RT during the non-BB gaming state from the non-RT gaming state Transition to gaming state.

  On the other hand, when the current gaming state is the first RT gaming state, when “BB” is won by an internal lottery process described later, the first RT gaming state is shifted to the fifth RT gaming state.

  In addition, when the current gaming state is the first RT gaming state and the “combination of symbols relating to the third RT gaming state transition replay” is displayed on the active line, the third RT in the non-BB state from the first RT gaming state. Transition to gaming state.

  On the other hand, when the current gaming state is the second RT gaming state during BB and “RB” is won by the internal lottery process described later, the second RT gaming state during BB is shifted to the third RT gaming state during BB. .

  In addition, when the current gaming state is the second RT gaming state during BB and the BB termination condition is satisfied, the second RT gaming state during BB is shifted to the second RT gaming state during non-BB.

  On the other hand, when the current gaming state is the second RT gaming state during non-BB and the “combination of symbols relating to the third RT gaming state transition replay” is displayed on the active line, the second RT gaming state during non-BB To the non-BB third RT gaming state.

  Further, when the current gaming state is the second RT gaming state during non-BB, and when “BB” is won by an internal lottery process described later, the second RT gaming state during non-BB is shifted to the fifth RT gaming state. .

  On the other hand, when the current gaming state is the third RT gaming state during BB and the “combination of symbols relating to JAC” is displayed on the active line, the RB gaming state during the third RT from the third RT gaming state during BB It is transferred to.

  In addition, when the current gaming state is the third RT gaming state during BB and the BB termination condition is satisfied, the state is shifted from the third RT gaming state during BB to the third RT gaming state during non-BB.

  On the other hand, when the current gaming state is the third RT gaming state during non-BB and the “combination of symbols relating to the fourth RT gaming state transition replay” is displayed on the active line, the third RT gaming state during non-BB To 4th RT gaming state.

  Further, when the current gaming state is the third RT gaming state during non-BB, and when “BB” is won by an internal lottery process described later, the state shifts from the third RT gaming state during non-BB to the fifth RT gaming state. .

  On the other hand, when the current gaming state is the fourth RT gaming state, when the “combination of symbols relating to the first RT gaming state transition replay” is displayed on the active line, the fourth RT gaming state is changed to the first RT gaming state. Migrated.

  Further, when the current gaming state is the fourth RT gaming state, when “BB” is won by the internal lottery process described later, the fourth RT gaming state is shifted to the fifth RT gaming state.

  On the other hand, when the current gaming state is the fifth RT gaming state, the transition from the fifth RT gaming state to the second RT gaming state during BB is made when “the combination of symbols related to BB” is displayed on the active line. .

  On the other hand, when the current gaming state is the RB gaming state during the third RT, the transition from the RB gaming state during the third RT to the third RT gaming state during BB is performed when the RB termination condition is satisfied.

  Further, in the case where the current gaming state is the RB gaming state during the third RT, the RB gaming state during the third RT is shifted to the non-RT gaming state when the BB termination condition is satisfied.

(List of states managed by the main control board)
Next, a list of states managed by the main control board will be described based on FIG.

  The list of states managed by the main control board 300 is defined for the state names and the state numbers corresponding to the state names. Here, the states managed by the main control board 300 in this embodiment are the “normal state” with the state number “01”, the “BB ready state” with the state number “02”, and the state number “03”. “BB state”, “RB state” with state number “04”, “first fall standby state” with state number “05”, “ART ready state” with state number “06”, state number “07” ”ART state”, state number “08” “ART BB ready state”, state number “09” “ART BB state”, state number “10” “ART RB state”, A “second fall standby state” having a state number “11” is defined.

(State transition diagram managed by the main control board)
Next, a state transition diagram managed by the main control board will be described with reference to FIG.

  In the present embodiment, a plurality of states managed by the main control board 300 are provided separately from the gaming state controlled by the main control board 300. Hereinafter, description of each state and conditions for transition to each state will be given.

(Normal state)
The normal state is a disadvantageous state for the player. Here, in the present embodiment, in the normal state, when the BB is determined as the winning combination by an internal lottery process described later, a lottery is performed as to whether or not to shift to the ART ready state after the BB state ends. Is called. Thereby, the interest with respect to the game in a normal state is improved.

  Further, in the normal state, when BB is determined as a winning combination by an internal lottery process described later, control for shifting from the normal state to the BB preparation state is performed. Further, in the normal state, when the symbol combination related to the “third RT gaming state transition replay” is displayed on the active line, control for shifting from the normal state to the ART ready state is performed.

(BB ready state)
The BB preparation state is a state that is shifted when BB is determined as a winning combination by an internal lottery process described later. Specifically, in the BB preparation state, the left stop button 11, the middle at a timing at which a combination of symbols related to the BB corresponding to the winning combination determined by the internal lottery process described later can be displayed on the active line. By operating the stop button 12 and the right stop button 13, the combination of symbols related to BB can be displayed on the active line.

  Further, in the BB preparation state, when a combination of symbols related to BB is displayed on the active line, control for shifting from the BB preparation state to the BB state is performed.

(BB state)
The BB state is a state in which, in the BB preparation state, a transition is made based on the combination of symbols related to BB being displayed on the active line. Here, in the present embodiment, the BB state is determined by ART preparation when “success play”, “chance replay”, “cherry”, and “middle cherry” are determined as the winning combination by an internal lottery process described later. A lottery is performed as to whether or not to enter the state. Thereby, the interest with respect to the game in BB state is improved.

  Further, in the BB state, when a combination of symbols related to JAC is displayed on the active line, control for shifting from the BB state to the RB state is performed. Further, in the BB state, when the BB state ends and it is not determined to shift to the ART preparation state, control for shifting from the BB state to the first fall standby state is performed. Further, in the BB state, when the BB state ends and it is determined to shift to the ART ready state, control for shifting from the BB state to the ART ready state is performed.

(RB state)
The RB state is a state that is shifted when the symbol combination related to JAC is displayed on the active line in the BB state.

  Further, in the RB state, when the BB state termination condition is satisfied, control for shifting from the RB state to the normal state is performed. In the RB state, when the RB state ends and the BB state end condition is not satisfied, control for shifting from the RB state to the BB state is performed.

(First fall standby state)
The first fall standby state is a state in which, in the BB state, when the BB state ends without being determined to shift to the ART preparation state, the state transitions to the normal state.

  Further, in the first fall standby state, when a combination of symbols related to the first RT gaming state transition replay is displayed on the active line, control for shifting from the first fall standby state to the normal state is performed. Further, in the first fall standby state, when BB is determined as a winning combination by an internal lottery process described later, control is performed to shift from the first fall standby state to the BB preparation state.

(ART ready state)
The ART ready state is a state in which, when it is determined to shift to the ART state, the state is shifted to after shifting to the ART state after the BB state ends. Further, the ART ready state is a state that is transferred when a combination of symbols related to the third RT gaming state transition replay is displayed on the active line in the normal state.

  Further, in the ART ready state, when a combination of symbols related to the fourth RT gaming state transition replay is displayed on the active line, control for shifting from the ART ready state to the ART state is performed. Further, in the ART ready state, when BB is determined as a winning combination by an internal lottery process described later, control for shifting from the ART ready state to the BB ready state during ART is performed.

  In the ART preparation state, when “replay during RT3” is determined as the winning combination by the internal lottery process described later, the combination of symbols related to the fourth RT gaming state transition replay is displayed on the active line. The operation order of the left stop button 11, the middle stop button 12, and the right stop button 13 is notified.

(ART state)
In the ART state, when the “push order bell” is won by an internal lottery process described later, a left stop button is displayed in order to display the “combination of winning symbols” on the active line in an advantageous manner for the player. 11, the operation order of the middle stop button 12 and the right stop button 13 is informed. Thereby, the player operates the left stop button 11, the middle stop button 12, and the right stop button 13 in accordance with the notified operation order of the left stop button 11, the middle stop button 12, and the right stop button 13, thereby The “combination of symbols related to winning” can be displayed on the active line in an advantageous manner for the player.

  Further, in the ART state, when BB is determined as a winning combination by an internal lottery process to be described later, control for shifting from the ART state to the BB ready state during ART is performed. Further, in the ART state, when the value of an ART state game number counter, which will be described later, becomes “0”, control for shifting from the ART state to the second fall standby state is performed.

(BB ready state during ART)
The BB ready state during ART is a state that shifts when BB is won in the ART state. Specifically, in the BB ready state during ART, as in the BB ready state, a combination of symbols related to the BB corresponding to the winning combination determined by the internal lottery process described later can be displayed on the active line. By operating the left stop button 11, the middle stop button 12, and the right stop button 13 at the timing, the combination of symbols related to BB can be displayed on the effective line.

  Further, in the ART BB preparation state, when a combination of symbols related to BB is displayed on the active line, control is performed to shift from the ART BB preparation state to the ART BB state.

(BB state during ART)
The BB state during ART is a state that is shifted based on the combination of symbols related to BB being displayed on the active line in the ART state. Here, in the present embodiment, the BB state is the ART state when “success play”, “chance replay”, “cherry”, and “middle cherry” are determined as the winning combination by an internal lottery process described later. A lottery is performed as to whether or not the number of games that can be played is added. Thereby, the interest in the game in the BB state during ART is improved.

  Further, in the BB state during ART, when the BB state ends, control is performed to shift from the BB state during ART to the ART preparation state. Further, when the combination of symbols related to JAC is displayed on the active line in the BB state during ART, control for shifting from the BB state during ART to the RB state during ART is performed.

(RB state during ART)
The RB state during ART is a state that is shifted when a combination of symbols related to JAC is displayed on the active line in the BB state during ART.

  Further, in the RB state during ART, when the termination condition for the BB state during ART is satisfied, control for shifting from the RB state during ART to the ART state is performed. Further, in the RB state during ART, when the RB state is terminated and the termination condition for the BB state is not satisfied, control for shifting from the RB state during ART to the BB state during ART is performed.

(Second fall standby state)
The second fall standby state is a state in which after the ART state is finished, the state is shifted to the normal state.

  Further, in the second fall standby state, when a combination of symbols related to the first RT gaming state transition replay is displayed on the active line, control for shifting from the second fall standby state to the normal state is performed. Further, in the second fall standby state, when BB is determined as a winning combination by an internal lottery process described later, control is performed to shift from the second fall standby state to the BB ready state during ART.

(ART status lottery table for BB winning)
Next, based on FIG. 22, the BB winning time ART state transition lottery table will be described.

  The BB winning ART state transition lottery table is provided in the main ROM 302. In the normal state or the first fall standby state, when “BB” is won, it is determined whether or not to shift to the ART state. Provided to do. Specifically, in the ART state shift lottery table for BB winning, a lottery value that will shift to the ART state for each winning combination is defined. For example, when “Red Seven BB” with the winning number “28” is determined as the winning combination, it is determined to shift to the ART state with a probability of “32768/65536”.

(Bart ART state transfer lottery table)
Next, based on FIG. 23, the BB ART state transition lottery table will be described.

  The BB ART state transition lottery table is provided in the main ROM 302, and is provided for performing a lottery on whether or not to shift to the ART state in the BB state. Specifically, in the BB ART state transition lottery table, a lottery value that will shift to the ART state for each winning combination is defined. For example, when “success play” with the winning number “19” is determined as the winning combination, it is determined to shift to the ART state with a probability of “8192/65536”.

(ART state extra lottery table)
Next, the ART state extra lottery table will be described with reference to FIG.

  The ART state extra lottery table is provided in the main ROM 302, and is provided for performing a lottery on whether or not to add the number of games that can be played in the ART state in the ART state. Specifically, in the extra lottery table for ART state, a lottery value for the number of extra games is defined for each winning combination. For example, in the case where “successful play” with a winning number “19” is determined as a winning combination by an internal lottery process described later, “30” games are determined as the number of additional games with a probability of “4096/65536” “50” games are determined as the number of additional games with a probability of “2048/65536”, and “100” games are determined as the number of additional games with a probability of “1024/65536”.

(BB on top lottery table)
Next, based on FIG. 25, the BB medium addition lottery table will be described.

  The BB extra lottery table is provided in the main ROM 302, and is provided for performing a lottery on whether or not to add the number of games that can be played in the ART state in the BB state during ART. More specifically, the lottery table in the BB includes a lottery value for the number of extra games for each winning combination. For example, in the case where “successful play” with a winning number “19” is determined as a winning combination by an internal lottery process described later, “30” games are determined as the number of additional games with a probability of “6553/65536” “50” games are determined as the number of additional games with a probability of “2048/65536”, and “100” games are determined as the number of additional games with a probability of “1024/65536”.

(Direction decision table)
Next, the effect determination table will be described with reference to FIG.

  The effect determination table is provided in the sub ROM 402 and is provided for determining effects to be performed in each state managed by the main control board 300. Specifically, “production No.” and production contents corresponding to “production No.” are defined. In the effect determination table, conditions for executing effects such as a state managed by the main control board 300 are defined.

  Here, in the present embodiment, the effect determination table includes (A) a normal state effect determination table (see FIG. 26A) used when the state managed by the main control board 300 is the normal state, and ( B) BB preparation state effect determination table (see FIG. 26B) used when the state managed by the main control board 300 is the BB preparation state, and (C) the state managed by the main control board 300. BB state effect determination table (see FIG. 26C) used in the BB state, and (D) RB state effect determination table used when the state managed by the main control board 300 is the RB state ( 26D) and (E) the first fall standby state effect determination table used when the state managed by the main control board 300 is the first fall standby state. (See FIG. 26E), (F) an ART preparation state effect determination table (see FIG. 26F) used when the state managed by the main control board 300 is the ART preparation state, and (G ) ART state effect determination table (not shown) used when the state managed by the main control board 300 is the ART state, and (H) When the state managed by the main control board 300 is the BB state during ART. Art BB state effect determination table (not shown) used for the above, and (I) ART RB state effect determination table (FIG. 5) used when the state managed by the main control board 300 is the ART RB state. And (J) a second fall standby state effect determination table (FIG. 5) used when the state managed by the main control board 300 is the second fall standby state. Without) are provided.

(Program start processing by the main control board 300)
Next, a program start process performed by the main control board 300 will be described with reference to FIG. The program start process is a process performed based on the fact that the power switch 201sw is turned on.

(Step S1)
In step S <b> 1, the main CPU 301 performs processing for determining whether or not power is interrupted. Specifically, when power is supplied to the gaming machine 1, the main CPU 301 determines whether or not the gaming machine 1 is in a power interruption state, and when the power is not supplied to the gaming machine 1. In this case, a process for determining whether or not the gaming machine 1 is cut off by the backup power source is performed. If it is determined that the power is interrupted (step S1 = Yes), the process of step S1 is repeatedly executed. On the other hand, if it is determined that the power is not interrupted (step S1 = No), the process proceeds to step S2.

(Step S2)
In step S2, the main CPU 301 performs an initial setting process. Specifically, the main CPU 301 sets a table address for setting the internal register of the gaming machine 1, and performs a process of setting the register address based on the table. Then, when the process of step S2 ends, the process proceeds to step S3.

(Step S3)
In step S3, the main CPU 301 performs a RAM checksum calculation process. Specifically, the main CPU 301 calculates the checksum of the main RAM 303, and when the calculation is completed, performs processing for setting the checksum of the main RAM 303. Then, when the process of step S3 ends, the process proceeds to step S4.

(Step S4)
In step S4, the main CPU 301 performs a process for determining whether or not the setting change key switch is ON. In the present embodiment, the setting change key switch 48sw is turned on when the setting change key (not shown) is inserted into the setting change key hole 47 and rotated by a predetermined angle. Therefore, in step S4, the main CPU 301 performs a process of determining whether or not the setting change key (not shown) is rotated by a predetermined angle in a state where the setting change key (not shown) is inserted into the setting change key hole 47. When it is determined that the setting change key switch is ON (step S4 = Yes), the process proceeds to step S5, and when it is determined that the setting change key switch is OFF (step S4). = No), the processing shifts to a power failure recovery process for restoring the value of the register saved before power interruption and the value of the saved stack pointer.

  When the power interruption recovery process is completed, the game machine 1 returns to the state when the power is turned off.

(Step S5)
In step S5, the main CPU 301 performs a process of determining whether or not the door opening / closing sensor is ON. In the present embodiment, a door key (not shown) is inserted into the keyhole 5 and rotated clockwise by a predetermined angle, and the front door 3 is opened by a predetermined angle or more, whereby the door opening / closing sensor 17s is turned on. It becomes. Therefore, in step S5, the main CPU 301 determines whether or not a door key (not shown) is inserted into the keyhole 5 and rotated clockwise by a predetermined angle, and the front door 3 is opened at a predetermined angle or more. Processing to determine is performed. If it is determined that the door opening / closing sensor is ON (step S5 = Yes), the process proceeds to step S7, and if it is determined that the door opening / closing sensor is OFF (step S5 = No). ), The process proceeds to step S6.

(Step S6)
In step S6, the main CPU 301 performs a process of setting a setting change device operation abnormality flag. Specifically, when the setting change key switch 48sw is ON (step S4 = Yes) and the door opening / closing sensor 17s is OFF (step S5 = No), the front door 3 is not opened more than a predetermined angle. Nevertheless, it is rotated by a predetermined angle with the setting change key inserted. For this reason, the main CPU 301 performs a process of setting a setting change device operation abnormality flag in a setting change device operation abnormality flag storage area provided in the main RAM 303. And when the process of step S6 is complete | finished, a process is transfered to the electric power interruption return process mentioned above.

(Step S7)
In step S7, the main CPU 301 performs a setting value change process. Specifically, the main CPU 301 acquires the current set value, determines whether or not the range of the set value is normal, and when the determination result is normal, the stored number indicator 28, Processing for displaying the current set value on the payout number display 29, the setting display unit 43, and the like is performed. On the other hand, when the above determination result is not normal, processing for setting the initial setting value of the setting value in the setting value storage area provided in the main RAM 303 is performed. Then, the main CPU 301 performs setting value switching processing based on the detection of the operation of the setting change button 44 by the setting change switch 44sw, and also detects that the operation of the start lever 10 is detected by the start switch 10sw. Based on this, the setting value is determined, and the setting value is stored in the main RAM 303 when it is detected that the setting changing key rotated by a predetermined angle has been rotated to an angle at which it can be inserted and removed. Processing to store in the set value storage area provided is performed. Then, when the process of step S7 ends, the process proceeds to step S8.

(Step S8)
In step S8, the main CPU 301 performs a process of determining whether or not the door opening / closing sensor is OFF. Specifically, the main CPU 301 performs processing for determining whether or not the door opening / closing sensor 17s is OFF. If it is determined that the door opening / closing sensor is OFF (step S8 = Yes), the process proceeds to step S9, and if it is determined that the door opening / closing sensor is not OFF (step S8 = No). ), The process proceeds to step S10.

(Step S9)
In step S9, the main CPU 301 performs processing for setting a door close command. Specifically, the main CPU 301 performs a process of setting the door close command in the main transmission data storage area provided in the main RAM 303 in order to transmit the door close command to the sub control board 400. . Here, the “door close command” is a command having information indicating that the front door 3 is closed. Then, when the process of step S9 ends, the process proceeds to the main loop process (see FIG. 28).

(Step S10)
In step S10, the main CPU 301 performs processing for setting a door open command. Specifically, the main CPU 301 performs a process of setting the door open command in a main transmission data storage area provided in the main RAM 303 in order to transmit the door open command to the sub-control board 400. . Here, the “door open command” is a command having information indicating that the front door 3 is open. Then, when the process of step S10 ends, the process proceeds to the main loop process (see FIG. 28).

(Main loop processing by the main control board 300)
Next, the main loop process performed by the main control board 300 will be described based on FIG.

(Step S101)
In step S101, the main CPU 301 performs an initialization process. Specifically, the main CPU 301 sets the stack pointer, sets the initialization start address and the initialization end address of the main RAM 303, and then initializes from the initialization start address to the initialization end address area of the main RAM 303. Processing for initializing the area is performed. Then, when the process of step S101 ends, the process proceeds to step S102.

(Step S102)
In step S102, the main CPU 301 performs a game start management process. Specifically, the main CPU 301 determines the value of the insertion number counter provided in the main RAM 303, the value of the stop control number storage area provided in the main RAM 303, and the press reference position storage area provided in the main RAM 303. Performs processing to clear the value. Then, when the process of step S102 ends, the process proceeds to step S103.

(Step S103)
In step S103, the main CPU 301 performs a start lever check process, which will be described in detail later with reference to FIG. In the processing, the main CPU 301 performs processing for determining whether or not the start switch 10sw is ON. Then, when the process of step S103 ends, the process proceeds to step S104.

(Step S104)
In step S104, the main CPU 301 performs an internal lottery process, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of determining a winning combination by lottery. Then, when the process of step S104 ends, the process proceeds to step S105.

(Step S105)
In step S105, the main CPU 301 performs bonus information update processing which will be described in detail later with reference to FIG. In the processing, the main CPU 301 performs processing for updating a carry flag storage area provided in the main RAM 303 and the like. Then, when the process of step S105 ends, the process proceeds to step S106.

(Step S106)
In step S <b> 106, the main CPU 301 performs a start state process which will be described in detail later with reference to FIG. 32. In the processing, the main CPU 301 performs processing according to the state managed by the main control board 300. Then, when the process of step S106 ends, the process proceeds to step S107.

(Step S107)
In step S107, the main CPU 301 performs a symbol code setting process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of acquiring a stop control number based on the winning combination determined by the internal lottery process in step S104 and storing it in a stop control number storage area provided in the main RAM 303. . Then, when the process of step S107 ends, the process proceeds to step S108.

(Step S108)
In step S108, the main CPU 301 performs a reel rotation start preparation process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process for setting a minimum game time. Then, when the process of step S108 ends, the process proceeds to step S109.

(Step S109)
In step S109, the main CPU 301 performs reel stop pre-processing which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a pull-in prediction process for the rotating left reel 18, middle reel 19, and right reel 20. Then, when the process of step S109 ends, the process proceeds to step S110.

(Step S110)
In step S110, the main CPU 301 performs a reel rotation flag setting process. Specifically, the main CPU 301 performs processing for storing information indicating that the left reel 18, the middle reel 19, and the right reel 20 are rotating in a reel information storage area provided in the main RAM 303. Then, when the process of step S110 ends, the process proceeds to step S111.

(Step S111)
In step S111, the main CPU 301 performs a reel rotation start process. Specifically, the main CPU 301 drives the left stepping motor 151, the middle stepping motor 152, and the right stepping motor 153 via the reel control board 150 to determine the left reel 18, the middle reel 19, and the right reel 20. Performs processing to rotate at high speed. Then, when the process of step S111 ends, the process proceeds to step S112.

(Step S112)
In step S112, the main CPU 301 performs processing for setting an operable state flag. Specifically, the main CPU 301 performs processing for turning on the operable state flag corresponding to the left stop button 11, the middle stop button 12, and the right stop button 13 in the operable state flag storage area provided in the main RAM 303. Do. Then, when the process of step S112 ends, the process proceeds to step S113.

(Step S113)
In step S113, the main CPU 301 performs a reel rotation process which will be described in detail later with reference to FIG. In this process, the main CPU 301 detects that the left stop switch 11sw, middle stop switch 12sw, and right stop switch 13sw have detected a stop operation on the left stop button 11, the middle stop button 12, and the right stop button 13 by the player. Then, processing for stopping the rotation of the left reel 18, the middle reel 19, and the right reel 20 is performed. Then, when the process of step S113 ends, the process proceeds to step S114.

(Step S114)
In step S114, the main CPU 301 determines whether all reels have stopped. Specifically, the main CPU 301 determines whether all of the left reel 18, the middle reel 19, and the right reel 20 have stopped based on the value of the operable state flag storage area provided in the main RAM 303. I do. If it is determined that all reels have stopped (step S114 = Yes), the process proceeds to step S115. If it is determined that all reels have not stopped (step S114 = No), The process proceeds to step S113, and the same process is repeated until all reels stop.

(Step S115)
In step S115, the main CPU 301 performs display determination command reception standby processing, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of waiting until a display determination command is received from the payout board 350. Then, when the process of step S115 ends, the process proceeds to step S116.

(Step S116)
In step S116, the main CPU 301 performs a medal payout end command reception standby process which will be described in detail later with reference to FIG. In the process, the main CPU 301 performs a process of waiting until a medal payout end command is received from the payout board 350. Then, when the process of step S116 ends, the process proceeds to step S117.

(Step S117)
In step S117, the main CPU 301 performs a game state transition process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the gaming state based on the combination of symbols displayed on the active line. Then, when the process of step S117 ends, the process proceeds to step S118.

(Step S118)
In step S118, the main CPU 301 performs processing according to display state, which will be described in detail later with reference to FIG. In the processing, the main CPU 301 performs processing according to the combination of the state managed by the main control board 300 and the symbols displayed on the active line. Then, when the process of step S118 ends, the process proceeds to step S101, and the main loop process is repeatedly executed.

(Start lever check processing)
Next, based on FIG. 29, the start lever check process performed by the process of step S103 of FIG. 28 will be described. FIG. 29 is a diagram showing a subroutine of start lever check processing.

(Step S103-1)
In step S103-1, the main CPU 301 performs processing for determining whether or not the start switch is ON. Specifically, the main CPU 301 performs a process of determining whether or not the start switch 10sw has detected an operation of the start lever 10 by the player. When it is determined that the start switch is ON (step S103-1 = Yes), the process proceeds to step S103-2, and when it is determined that the start switch is not ON (step S103). -1 = No), the process of step S103-1 is repeatedly executed.

(Step S103-2)
In step S103-2, the main CPU 301 performs a process of determining whether or not the value of the insertion number counter is “3”. Specifically, the main CPU 301 performs a process of determining whether or not the value of the insertion number counter provided in the main RAM 303 is “3”. If it is determined that the value of the inserted number counter is “3” (step S103-2 = Yes), the process proceeds to step S103-3, and the value of the inserted number counter is not “3”. Is determined (step S103-2 = No), the process proceeds to step S103-1.

(Step S103-3)
In step S103-3, the main CPU 301 performs a process of turning off the re-game operating flag. Specifically, the main CPU 301 performs processing for turning off the value of the re-game operating flag storage area provided in the main RAM 303. When the process of step S103-3 is completed, the start lever check process subroutine is terminated, and the process proceeds to step S104 of the main loop process.

(Internal lottery process)
Next, based on FIG. 30, the internal lottery process performed by the process of step S104 of FIG. 28 will be described. FIG. 30 is a diagram showing a subroutine of the internal lottery process.

(Step S104-1)
In step S104-1, the main CPU 301 performs a pre-lottery error check process. Specifically, the main CPU 301 performs a process of detecting an error before determining the winning combination by the internal lottery process. Then, when the process of step S104-1 ends, the process proceeds to step S104-2.

  The main CPU 301 performs a non-recoverable error process when an error is detected by the pre-lottery error check process in step S104-1.

(Step S104-2)
In step S104-2, the main CPU 301 performs a hard random number acquisition process. Specifically, the main CPU 301 performs processing for extracting the random number value generated by the main random number generator 304 and processing for storing the extracted random number value in a register. Then, when the process of step S104-2 ends, the process proceeds to step S104-3.

(Step S104-3)
In step S104-3, the main CPU 301 performs a winning number initial value acquisition process. Specifically, the main CPU 301 performs processing for obtaining an initial value of a winning number when determining a winning combination. Here, in the present embodiment, the main CPU 301 performs processing of acquiring “48” as the initial value of the winning number and storing it in the register. Then, when the process of step S104-3 ends, the process proceeds to step S104-4.

(Step S104-4)
In step S104-4, the main CPU 301 performs a gaming state acquisition process. Specifically, the main CPU 301 performs processing for acquiring a gaming state based on the value of the gaming state storage area provided in the main RAM 303. Then, when the process of step S104-4 ends, the process proceeds to step S104-5.

(Step S104-5)
In step S104-5, the main CPU 301 performs processing for setting a winning combination determination table. Specifically, the main CPU 301 performs a process of setting a winning combination determination table stored in the main ROM 302 based on the gaming state acquired by the gaming state acquisition process of step S104-4. Then, when the process of step S104-5 ends, the process proceeds to step S104-6.

(Step S104-6)
In step S104-6, the main CPU 301 performs a lottery data acquisition process. Specifically, the main CPU 301 acquires data related to the winning combination corresponding to the winning number based on the winning combination determination table set by the process of step S104-5 and the winning number stored in the register. Process. Then, when the process of step S104-6 ends, the process proceeds to step S104-7.

(Step S104-7)
In step S104-7, the main CPU 301 performs a lottery value acquisition process. Specifically, the main CPU 301 performs a process of acquiring the lottery value of the currently selected winning combination determination table based on the winning number stored in the register and storing it in the register. Then, when the process of step S104-7 ends, the process proceeds to step S104-8.

(Step S104-8)
In step S104-8, the main CPU 301 performs a lottery confirmation process. Specifically, the main CPU 301 subtracts the lottery value acquired by the lottery value acquisition process in step S104-7 from the random value stored in the register, and subtracts the value of the register in which the random number value is stored. The process of updating to the value after storage and storing it is performed. Then, when the process of step S104-8 ends, the process proceeds to step S104-9.

(Step S104-9)
In step S104-9, the main CPU 301 performs a process of determining whether or not the winning is made. Specifically, the main CPU 301 performs a process of subtracting the lottery value acquired by the lottery value acquisition process of step S104-7 from the random number value stored in the register by the lottery confirmation process of step S104-8. Processing for determining whether or not the value is negative is performed. If it is determined that the winning is made (step S104-9 = Yes), the internal lottery process subroutine is terminated, and the process proceeds to step S105 of the main loop process. On the other hand, when it is determined that the winning is not made (step S104-9 = No), the process proceeds to step S104-10.

  If it is determined that the winning combination is made (step S104-9 = Yes), the winning combination corresponding to the winning number stored in the register is determined. Specifically, the main CPU 301 performs a process of turning on the condition device corresponding to the winning number in the winning combination storing area provided in the main RAM 303.

(Step S104-10)
In step S104-10, the main CPU 301 performs a process of subtracting “1” from the value of the winning number. Specifically, the main CPU 301 performs a process of subtracting “1” from the winning number stored in the register. Then, when the process of step S104-10 ends, the process proceeds to step S104-11.

(Step S104-11)
In step S104-11, the main CPU 301 performs processing for determining whether or not the value of the winning number is “0”. Specifically, the main CPU 301 determines whether or not the value of the winning number is “0” as a result of subtracting “1” from the winning number value stored in the register by the process of step S104-10. Perform the process. If it is determined that the value of the winning number is “0” (step S104-11 = Yes), the internal lottery process subroutine is terminated, and the process proceeds to step S105 of the main loop process. On the other hand, when it is determined that the value of the winning number is not “0” (step S104-11 = No), the process proceeds to step S104-4.

  In the present embodiment, when the value of the winning number is “0” (step S104-11 = YES), “losing” is determined as the winning combination.

(Bonus information update process)
Next, the bonus information update process performed by the process of step S105 of FIG. 28 will be described based on FIG. FIG. 31 shows a subroutine for bonus information update processing.

(Step S105-1)
In step S105-1, the main CPU 301 performs a process of determining whether or not the value of the winning number is “28” or more. Specifically, the main CPU 301 performs a process of determining whether or not the value of the winning number of the winning combination determined by the internal lottery process in step S104 is “28” or more. If it is determined that the value of the winning number is “28” or more (step S105-1 = Yes), the process proceeds to step S105-2, and the value of the winning number is not “28” or more. Is determined (step S105-1 = No), the process proceeds to step S105-6.

(Step S105-2)
In step S105-2, the main CPU 301 performs a carry flag storage area update process. Specifically, the main CPU 301 performs a process of updating the value of the carry flag storage area provided in the main RAM 303 based on the bonus type determined by the internal lottery process in step S104. For example, when “Red Seven BB” of the winning number “28” is determined by the internal lottery process in step S104, the bit corresponding to “same color red BB” in the carry flag storage area provided in the main RAM 303 A process to turn ON is performed. Then, when the process of step S105-2 ends, the process proceeds to step S105-3.

(Step S105-3)
In step S105-3, the main CPU 301 performs a process of determining whether or not the value of the winning number is “48”. Specifically, the main CPU 301 performs a process of determining whether or not the value of the winning number of the winning combination determined by the internal lottery process in step S104 is “48”. If it is determined that the value of the winning number is “48” (step S105-3 = Yes), the process proceeds to step S105-4, and it is determined that the value of the winning number is not “48”. If it is determined (step S105-3 = No), the process proceeds to step S105-5.

(Step S105-4)
In step S105-4, the main CPU 301 performs a process of shifting the gaming state to the third RT gaming state during BB. Specifically, the main CPU 301 performs processing for setting information relating to the third RT gaming state during BB in the gaming state storage area provided in the main RAM 303. When the process of step S105-4 ends, the bonus information update process subroutine ends, and the process proceeds to step S106 of the main loop process.

(Step S105-5)
In step S105-5, the main CPU 301 performs processing for shifting the gaming state to the fifth RT gaming state. Specifically, the main CPU 301 performs processing for setting information related to the fifth RT gaming state in a gaming state storage area provided in the main RAM 303. When the process of step S105-5 ends, the bonus information update process subroutine ends, and the process proceeds to step S106 of the main loop process.

(Step S105-6)
In step S105-5, the main CPU 301 performs a bonus flag setting process. Specifically, the main CPU 301 performs an exclusive OR operation between the value of the winning combination storage area provided in the main RAM 303 and the value of the carry flag storage area provided in the main RAM 303, and the calculation result is obtained. Processing for storing in the winning combination storage area provided in the main RAM 303 is performed. When the process of step S105-6 ends, the bonus information update process subroutine ends, and the process proceeds to step S106 of the main loop process.

(Processing by status at start)
Next, based on FIG. 32, a description will be given of the start-time state process performed by the process of step S106 of FIG. FIG. 32 is a diagram showing a subroutine of processing by state at start time.

(Step S106-1)
In step S <b> 106-1, the main CPU 301 performs a process of determining whether or not the state number is “01”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “01”. When it is determined that the state number is “01” (step S106-1 = Yes), the process proceeds to step S106-2, and when it is determined that the state number is not “01”. (Step S106-1 = No), the process proceeds to Step S106-3.

(Step S106-2)
In step S <b> 106-2, the main CPU 301 performs normal state processing which will be described in detail later with reference to FIG. 33. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the BB preparation state when “BB” is won. Then, when the process of step S106-2 is completed, the subroutine for the start-time state process is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-3)
In step S106-3, the main CPU 301 performs a process of determining whether or not the state number is “03”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “03”. When it is determined that the state number is “03” (step S106-3 = Yes), the process proceeds to step S106-4, and when it is determined that the state number is not “03”. (Step S106-3 = No), the process proceeds to Step S106-5.

(Step S106-4)
In step S106-4, the main CPU 301 performs processing for the BB state, which will be described in detail later with reference to FIG. In the process, the main CPU 301 performs a process of drawing whether or not to shift to the ART state after the end of the BB state. Then, when the process of step S106-4 is completed, the subroutine for the start-time state process is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-5)
In step S106-5, the main CPU 301 performs a process of determining whether or not the state number is “05”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “05”. When it is determined that the state number is “05” (step S106-5 = Yes), the process proceeds to step S106-6, and when it is determined that the state number is not “05”. (Step S106-5 = No), the process proceeds to Step S106-7.

(Step S106-6)
In step S106-6, the main CPU 301 performs a first fall standby state process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the BB preparation state when “BB” is won. Then, when the process of step S106-6 is completed, the subroutine of the start-time state process is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-7)
In step S106-7, the main CPU 301 performs a process of determining whether or not the state number is “06”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “06”. When it is determined that the state number is “06” (step S106-7 = Yes), the process proceeds to step S106-8, and when it is determined that the state number is not “06”. (Step S106-7 = No), the process proceeds to Step S106-9.

(Step S106-8)
In step S106-8, the main CPU 301 performs an ART preparation state process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the BB preparation state during ART when “BB” is won. Then, when the process of step S106-8 is completed, the subroutine of the start-time state process is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-9)
In step S106-9, the main CPU 301 performs a process of determining whether or not the state number is “07”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “07”. When it is determined that the state number is “07” (step S106-9 = Yes), the process proceeds to step S106-10, and when it is determined that the state number is not “07”. (Step S106-9 = No), the process proceeds to Step S106-11.

(Step S106-10)
In step S106-10, the main CPU 301 performs an ART state process, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of subtracting “1” from the value of the ART state game number counter provided in the main RAM 303. When the process of step S106-10 is completed, the subroutine of the start-time state process is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-11)
In step S <b> 106-11, the main CPU 301 performs processing for determining whether or not the state number is “09”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “09”. When it is determined that the state number is “09” (step S106-11 = Yes), the process proceeds to step S106-12, and when it is determined that the state number is not “09”. (Step S106-11 = No), the process proceeds to Step S106-13.

(Step S106-12)
In step S106-12, the main CPU 301 performs processing for the BB state during ART, which will be described in detail later with reference to FIG. In the process, the main CPU 301 performs a process of drawing whether or not to increase the number of games that can be played in the ART state. Then, when the process of step S106-12 is completed, the subroutine for the start-time state process is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-13)
In step S106-13, the main CPU 301 performs processing for determining whether or not the state number is “11”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “11”. When it is determined that the state number is “11” (step S106-13 = Yes), the process proceeds to step S106-14, and when it is determined that the state number is not “11”. (Step S106-13 = No), the subroutine for the state process at the start time is terminated, and the process proceeds to Step S107 of the main loop process.

(Step S106-14)
In step S106-14, the main CPU 301 performs a second fall standby state process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the BB preparation state during ART when “BB” is won. Then, when the process of step S106-14 is completed, the subroutine of the start-time state process is terminated, and the process proceeds to step S107 of the main loop process.

(Normal processing)
Next, based on FIG. 33, the normal state process performed by the process of step S106-2 of FIG. 32 will be described. FIG. 33 is a diagram showing a subroutine for normal state processing.

(Step S106-2-1)
In step S106-2-1, the main CPU 301 performs a process of determining whether or not the value of the winning number is “28” or more. Specifically, the main CPU 301 performs a process of determining whether or not the value of the winning number of the winning combination determined by the internal lottery process in step S104 is “28” or more. When it is determined that the value of the winning number is “28” or more (step S106-2-1 = Yes), the process proceeds to step S106-2-2, and the value of the winning number is “28”. If it is determined that it is not greater than or equal to “No” (step S106-2-1 = No), the subroutine for the normal state process is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-2-2)
In step S106-2-2, the main CPU 301 performs a BB winning ART state transition lottery process. Specifically, the main CPU 301 sets the values stored in the BB winning ART state transition lottery table (see FIG. 22) provided in the main ROM 302 and the winning combination storage area provided in the main RAM 303. Based on this, after the end of the BB state, the lottery process is performed to determine whether or not to shift to the ART state. Then, when the process of step S106-2-2 ends, the process proceeds to step S106-2-3.

(Step S106-2-3)
In step S106-2-3, the main CPU 301 performs a process of determining whether or not the winning is made. Specifically, the main CPU 301 performs a process of determining whether or not to shift to the ART state is determined as a result of the lottery by the BB winning ART state transition lottery process in step S106-2-2. If it is determined that the winning is made (step S106-2-3 = Yes), the process proceeds to step S106-2-4, and if it is determined that the winning is not made (step S106-2). -3 = No), the process proceeds to step S106-2-5.

(Step S106-2-4)
In step S106-2-4, the main CPU 301 performs processing for turning on the ART winning flag. Specifically, the main CPU 301 performs a process of turning on the ART winning flag in the ART winning flag storage area provided in the main RAM 303. Then, when the process of step S106-2-4 ends, the process proceeds to step S106-2-5.

(Step S106-2-5)
In step S106-2-5, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the BB preparation state. Specifically, the main CPU 301 performs processing for setting information relating to the BB preparation state in a state storage area provided in the main RAM 303. When the process of step S106-2-5 ends, the normal state processing subroutine ends, and the process proceeds to step S107 of the main loop process.

(Process for BB state)
Next, based on FIG. 34, the process for BB state performed by the process of step S106-4 of FIG. 32 is demonstrated. FIG. 34 is a diagram showing a subroutine of processing for the BB state.

(Step S106-4-1)
In step S106-4-1, the main CPU 301 performs a process of determining whether or not the ART winning flag is ON. Specifically, the main CPU 301 performs processing for determining whether or not the ART winning flag is ON based on the value stored in the ART winning flag storage area provided in the main RAM 303. When it is determined that the ART winning flag is ON (step S106-4-1 = Yes), the subroutine for the BB state process is terminated, and the process proceeds to step S107 of the main loop process. On the other hand, if it is determined that the ART winning flag is not ON (step S106-4-1 = No), the process proceeds to step S106-4-2.

(Step S106-4-2)
In step S106-4-2, the main CPU 301 performs an ART state lottery process during BB. Specifically, the main CPU 301 is based on the BB ART state transition lottery table (see FIG. 23) provided in the main ROM 302 and the value stored in the winning combination storage area provided in the main RAM 303. Then, after the BB state is finished, a process for drawing whether or not to shift to the ART state is performed. Then, when the process of step S106-4-2 ends, the process proceeds to step S106-4-3.

(Step S106-4-3)
In step S106-4-3, the main CPU 301 performs a process of determining whether or not a winning is made. Specifically, the main CPU 301 performs a process of determining whether or not to shift to the ART state is determined as a result of the lottery by the ART state shift lottery process during BB in step S106-4-2. And when it determines with having won (step S106-4-3 = Yes), it transfers a process to step S106-4-4, and when it determines with having not been won (step S106-4) -3 = No), the subroutine for the BB state process is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-4-4)
In step S106-4-4, the main CPU 301 performs processing for turning on the ART winning flag. Specifically, the main CPU 301 performs a process of turning on the ART winning flag in the ART winning flag storage area provided in the main RAM 303. When the process of step S106-4-4 ends, the subroutine for the BB state process ends, and the process proceeds to step S107 of the main loop process.

(Processing for the first fall standby state)
Next, based on FIG. 35, the first fall standby state process performed by the process of step S106-6 of FIG. 32 will be described. FIG. 35 is a diagram showing a subroutine of the first fall standby state processing.

(Step S106-6-1)
In step S <b> 106-6-1, the main CPU 301 performs processing for determining whether or not the value of the winning number is “28” or more. Specifically, the main CPU 301 performs a process of determining whether or not the value of the winning number of the winning combination determined by the internal lottery process in step S104 is “28” or more. When it is determined that the value of the winning number is “28” or more (step S106-6-1 = Yes), the process proceeds to step S106-6-2, and the value of the winning number is “28”. If it is determined that it is not greater than or equal to “No” (step S106-6-1 = No), the first fall standby state processing subroutine is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-6-2)
In step S106-6-2, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the BB preparation state. Specifically, the main CPU 301 performs processing for setting information relating to the BB preparation state in a state storage area provided in the main RAM 303. When the process of step S106-6-2 ends, the first fall standby state processing subroutine ends, and the process proceeds to step S107 of the main loop process.

  In the first fall standby state, when it is determined that the value of the winning number is “28” or more (step S106-6-1 = Yes), the BB winning time ART state provided in the main ROM 302 Based on the transfer lottery table (see FIG. 22) and the value stored in the winning combination storage area provided in the main RAM 303, a process for lottering whether to shift to the ART state after the BB state ends is performed. It is good as well.

(ART preparation status processing)
Next, based on FIG. 36, the ART preparation state process performed by the process of step S106-8 of FIG. 32 will be described. FIG. 36 is a diagram showing a subroutine of the ART preparation state processing.

(Step S106-8-1)
In step S106-8-1, the main CPU 301 performs a process of determining whether or not the value of the winning number is “28” or more. Specifically, the main CPU 301 performs a process of determining whether or not the value of the winning number of the winning combination determined by the internal lottery process in step S104 is “28” or more. If it is determined that the value of the winning number is “28” or more (step S106-8-1 = Yes), the process proceeds to step S106-8-2, and the value of the winning number is “28”. If it is determined that it is not greater than or equal to “No” (step S106-8-1 = No), the ART preparation state processing subroutine is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-8-2)
In step S106-8-2, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the BB preparation state during ART. Specifically, the main CPU 301 performs processing for setting information related to the BB preparation state during ART in a state storage area provided in the main RAM 303. When the processing of step S106-8-2 is completed, the ART preparation state processing subroutine is terminated, and the process proceeds to step S107 of the main loop processing.

(ART status processing)
Next, the ART state process performed by the process of step S106-10 of FIG. 32 will be described based on FIG. FIG. 37 is a diagram showing a subroutine of the ART state processing.

(Step S106-10-1)
In step S106-10-1, the main CPU 301 performs a process of subtracting “1” from the value of the ART state game number counter. Specifically, the main CPU 301 performs a process of subtracting “1” from the value of the ART state game number counter provided in the main RAM 303. Then, when the process of step S106-10-1 ends, the process proceeds to step S106-10-2.

(Step S106-10-2)
In step S <b> 106-10-2, the main CPU 301 performs a lottery process by adding the number of ART state games. Specifically, the main CPU 301 is based on an ART state extra lottery table (see FIG. 24) provided in the main ROM 302 and a value stored in the winning combination storage area provided in the main RAM 303. In the ART state, a process of lottery is performed to determine whether or not to increase the number of games that can be played. Then, when the process of step S106-10-2 ends, the process proceeds to step S106-10-3.

(Step S106-10-3)
In step S <b> 106-10-3, the main CPU 301 performs a process for determining whether or not it has been won. Specifically, the main CPU 301 determines whether or not it is determined to add an ART state game number counter as a result of performing the ART state game number adding lottery process in step S106-10-2. Do. And when it determines with having won (step S106-10-3 = Yes), it transfers a process to step S106-10-4, and when it determines with having not been won (step S106-10) -3 = No), the process proceeds to step S106-10-5.

(Step S106-10-4)
In step S106-10-4, the main CPU 301 performs an ART state game number counter addition process. Specifically, the main CPU 301 adds the number of ART state games to the value stored in the ART state game number counter provided in the main RAM 303, and the value determined by the lottery process in step S106-10-2. The process which adds is performed. Then, when the process of step S106-10-4 is completed, the process proceeds to step S106-10-5.

(Step S106-10-5)
In step S106-10-5, the main CPU 301 performs processing for determining whether or not the value of the winning number is “28” or more. Specifically, the main CPU 301 performs a process of determining whether or not the value of the winning number of the winning combination determined by the internal lottery process in step S104 is “28” or more. If it is determined that the value of the winning number is “28” or more (step S106-10-5 = Yes), the process proceeds to step S106-10-6, and the value of the winning number is “28”. If it is determined that it is not greater than or equal to “No” (step S106-10-5 = No), the process proceeds to step S106-10-7.

(Step S106-10-6)
In step S106-10-6, the main CPU 301 performs processing for shifting the state managed by the main control board 300 to the BB ready state during ART. Specifically, the main CPU 301 performs processing for setting information related to the BB preparation state during ART in a state storage area provided in the main RAM 303. When the process of step S106-10-6 is completed, the ART state subroutine is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-10-7)
In step S106-10-7, the main CPU 301 performs a process of determining whether or not the value of the ART state game number counter is “0”. Specifically, the main CPU 301 subtracts “1” from the value of the ART state game number counter provided in the main RAM 303 by the processing of step S106-10-1, and as a result, provides the ART provided in the main RAM 303. Processing for determining whether or not the value of the state game number counter is “0” is performed. If it is determined that the value of the ART state game number counter is “0” (step S106-10-7 = Yes), the process proceeds to step S106-10-8 to display the ART state game. If it is determined that the value of the number counter is not “0” (step S106-10-7 = No), the ART state subroutine is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-10-8)
In step S106-10-8, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the second fall standby state. Specifically, the main CPU 301 performs processing for setting information related to the second fall standby state in a state storage area provided in the main RAM 303. When the process of step S106-10-8 is completed, the ART state subroutine is terminated, and the process proceeds to step S107 of the main loop process.

(Process for BB status during ART)
Next, the processing for the BB state during ART performed by the processing of step S106-12 in FIG. 32 will be described based on FIG. FIG. 38 is a diagram showing a subroutine of processing for the BB state during ART.

(Step S106-12-1)
In step S106-12-1, the main CPU 301 performs a lottery process by adding the number of games for the BB state during ART. Specifically, the main CPU 301 determines the ART based on the value stored in the BB medium addition lottery table (see FIG. 25) provided in the main ROM 302 and the winning combination storage area provided in the main RAM 303. In the state, the lottery process is performed to determine whether or not to increase the number of games that can be played. Then, when the process of step S106-12-1 ends, the process proceeds to step S106-12-2.

(Step S106-12-2)
In step S <b> 106-12-2, the main CPU 301 performs a process for determining whether or not it has been won. Specifically, the main CPU 301 determines whether or not it is determined to add the ART state game number counter as a result of performing the lottery process for adding the number of games for the BB state during ART in step S106-12-2. Process. And when it determines with having won (step S106-12-2 = Yes), it transfers a process to step S106-12-3, and when it determines with having not been won (step S106-12) -2 = No), the subroutine for the BB state process during ART is terminated, and the process proceeds to step S107 of the main loop process.

(Step S106-12-3)
In step S106-12-3, the main CPU 301 performs ART state game number counter addition processing. Specifically, the main CPU 301 is determined by lottery processing by adding the number of games for the BB state during ART in step S106-12-1 to the value stored in the ART state game number counter provided in the main RAM 303. A process of adding to the ART state game number counter is performed. When the process of step S106-12-3 is completed, the ART BB state process subroutine is terminated, and the process proceeds to step S107 of the main loop process.

(Processing for second fall standby state)
Next, based on FIG. 39, the second fall standby state process performed by the process of step S106-14 of FIG. 32 will be described. FIG. 39 is a diagram showing a subroutine of the second fall standby state processing.

(Step S106-14-1)
In step S106-14-1, the main CPU 301 performs a process of determining whether or not the value of the winning number is “28” or more. Specifically, the main CPU 301 performs a process of determining whether or not the value of the winning number of the winning combination determined by the internal lottery process in step S104 is “28” or more. When it is determined that the value of the winning number is “28” or more (step S106-14-1 = Yes), the process proceeds to step S106-14-2, and the value of the winning number is “28”. If it is determined that it is not greater than or equal to “No” (step S106-14-1 = No), the second fall standby state processing subroutine is terminated, and the process proceeds to step S107 of the main loop processing.

(Step S106-14-2)
In step S <b> 106-14-2, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the BB preparation state during ART. Specifically, the main CPU 301 performs processing for setting information related to the BB preparation state during ART in a state storage area provided in the main RAM 303. When the process of step S106-14-2 is completed, the second fall standby state process subroutine is terminated, and the process proceeds to step S107 of the main loop process.

(Design code setting process)
Next, the symbol code setting process performed by the process of step S107 of FIG. 28 will be described based on FIG. FIG. 40 is a diagram showing a subroutine of symbol code setting processing.

(Step S107-1)
In step S107-1, the main CPU 301 performs a stop control number acquisition process. Specifically, the main CPU 301 stores the winning number of the winning combination determined by the internal lottery process in step S104 as a stop control number in the stop control number storage area provided in the main RAM 303 and sets it in the register. Process. Then, when the process of step S107-1 ends, the process proceeds to step S107-2.

(Step S107-2)
In step S107-2, the main CPU 301 performs processing for setting a reel rotation start acceptance command. Specifically, the main CPU 301 transmits the reel rotation start acceptance command to the payout board 350 and the sub control board 400, and transmits the reel rotation start acceptance command to the main transmission data provided in the main RAM 303. Performs processing to set in the storage area. Here, the “reel rotation start acceptance command” is a command having information indicating that the operation of the start lever 10 has been accepted. Then, when the process of step S107-2 ends, the process proceeds to step S107-3.

(Step S107-3)
In step S107-3, the main CPU 301 performs a spinning effect lottery process. In this process, the main CPU 301 performs a lottery process to determine whether or not to perform a spinning effect to rotate the left reel 18, the middle reel 19, and the right reel 20. If the lottery is won, The process which stores the information which concerns on the winning rotation effect information is performed in the rotation effect information storage area currently set. Then, when the process of step S107-3 ends, the process proceeds to step S107-4.

(Step S107-4)
In step S107-4, the main CPU 301 performs processing for setting a conditional device command. Specifically, the main CPU 301 sets the condition device command in the main transmission data storage area provided in the main RAM 303 in order to transmit the condition device command to the payout board 350 and the sub-control board 400. Perform the process. Here, the “condition device command” is a command having information related to the winning combination, information related to the spinning effect to be executed, and the like. When the process of step S107-4 is completed, the symbol code setting process subroutine is terminated, and the process proceeds to step S108 of the main loop process.

(Reel rotation start preparation process)
Next, the reel rotation start preparation process performed by the process of step S108 of FIG. 28 will be described based on FIG. FIG. 41 shows a subroutine for reel rotation start preparation processing.

(Step S108-1)
In step S108-1, the main CPU 301 performs a turning effect setting process. Specifically, the main CPU 301 performs processing for setting information for executing the spinning effect based on the information stored in the spinning effect information storage area provided in the main RAM 303, and A process for executing the trunk effect is performed. When the process of step S108-1 is completed, the process proceeds to step S108-2.

(Step S108-2)
In step S108-2, the main CPU 301 performs processing for determining whether or not the minimum game time has elapsed. Specifically, the main CPU 301 performs a process of determining whether or not the value of the timer counter set by the process of step S108-3 described later has become “0” in the previous game. When it is determined that the minimum game time has elapsed (step S108-2 = Yes), the process proceeds to step S108-3, and when it is determined that the minimum game time has not elapsed ( Step S108-2 = No), the process of Step S108-2 is repeatedly executed until the minimum game time has elapsed.

(Step S108-3)
In step S108-3, the main CPU 301 performs processing for setting the minimum game time. Specifically, the main CPU 301 is configured so that the time from the process of step S108-3 in the previous game to the process of step S108-2 in the current game is not less than the minimum game time in order to suppress gambling for the game. Then, a process for setting the minimum game time in the timer counter is performed. Here, in the present embodiment, the minimum game time is about “4.1” seconds. Then, when the process of step S108-3 ends, the process proceeds to step S108-4.

(Step S108-4)
In step S108-4, the main CPU 301 performs processing for setting a reel rotation start command. Specifically, the main CPU 301 performs a process of setting the reel rotation start command in the main transmission data storage area provided in the main RAM 303 in order to transmit the reel rotation start command to the sub-control board 400. Do. Here, the reel rotation start command is a command having information indicating that rotation of the left reel 18, the middle reel 19, and the right reel 20 is started. When the process of step S108-4 is completed, the reel rotation start preparation process subroutine is terminated, and the process proceeds to step S109 of the main loop process.

(Reel stop pretreatment)
Next, based on FIG. 42, the reel stop pre-process performed by the process of step S109 of FIG. 28 will be described. FIG. 42 shows a subroutine for reel stop pre-processing.

(Step S109-1)
In step S109-1, the main CPU 301 performs a process of setting an expected pull-in reel search initial value. Specifically, the main CPU 301 performs a process of setting data “100B” corresponding to the right reel 20 in the register as an expected pull-in reel search initial value. Then, when the process of step S109-1 ends, the process proceeds to step S109-2.

(Step S109-2)
In step S109-2, the main CPU 301 performs processing for determining whether or not the reel is rotating. Specifically, the main CPU 301 searches for the left of the search target reel based on the expected pull-in reel search initial value set in step S109-1 or the value of the search target reel updated in step S109-4 described below. A process of determining whether or not the reel 18, the middle reel 19, and the right reel 20 are rotating is performed. If it is determined that the reel is rotating (step S109-2 = Yes), the process proceeds to step S109-3. If it is determined that the reel is not rotating (step S109- 2 = No), the process proceeds to step S109-4.

(Step S109-3)
In step S109-3, the main CPU 301 performs a pull-in prediction process. Specifically, the main CPU 301 first sets the initial value of the virtual stop position, acquires the pull-in priority according to the virtual stop position, and stores it in the pull-in priority storage area provided in the main RAM 303. I do. Then, when the process of step S109-3 ends, the process proceeds to step S109-4.

  The main CPU 301 performs a process of clearing data stored in the pull-in priority storage area provided in the main RAM 303 at a predetermined timing by the pull-in prediction process in step S109-3.

(Step S109-4)
In step S109-4, the main CPU 301 performs processing for acquiring the next search target reel. Specifically, when it is determined that the search target reel is stopped (step S109-2 = No), the main CPU 301 performs the search target reel pull-in prediction process in the pull-in prediction process in step S109-3. When the processing is completed, the value set in the register is shifted to the right to obtain the next search target reel. Then, when the process of step S109-4 ends, the process proceeds to step S109-5.

(Step S109-5)
In step S109-5, the main CPU 301 performs a process of determining whether or not the processing of all reels has been completed. Specifically, the main CPU 301 performs a process of determining whether or not the pull-in prediction process for all of the left reel 18, the middle reel 19, and the right reel 20 has been completed. If it is determined that all reels have been processed (step S109-5 = Yes), the reel stop pre-processing subroutine is terminated, and the process proceeds to step S110 of the main loop process. On the other hand, if it is determined that all reels have not been processed (step S109-5 = No), the process proceeds to step S109-2, and all of the left reel 18, the middle reel 19, and the right reel 20 are processed. The same process is repeatedly executed until the pull-in prediction process for the reel is completed.

(Processing during reel rotation)
Next, based on FIG. 43, the reel rotation process performed by the process of step S113 of FIG. 28 will be described. FIG. 43 is a diagram showing a subroutine of reel rotation processing.

(Step S113-1)
In step S113-1, the main CPU 301 performs a process of determining whether or not the stop button is pressed. Specifically, the main CPU 301 determines whether or not the left stop switch 11sw, middle stop switch 12sw, and right stop switch 13sw have detected an operation of the left stop button 11, the middle stop button 12, and the right stop button 13 by the player. Processing to determine is performed. If it is determined that the stop button has been pressed (step S113-1 = Yes), the process proceeds to step S113-2, and if it is determined that the stop button has not been pressed (step S113). -1 = No), the reel rotation process subroutine is terminated, and the process proceeds to step S114 of the main loop process.

(Step S113-2)
In step S113-2, the main CPU 301 performs processing for turning off the operable state flag. Specifically, the main CPU 301 determines the left stop button 11 in the operable state flag storage area provided in the main RAM 303 based on the operated left stop button 11, middle stop button 12, and right stop button 13. Processing to turn off the operable flag corresponding to the stop button 12 and the right stop button 13 is performed. Then, when the process of step S113-2 ends, the process proceeds to step S113-3.

(Step S113-3)
In step S113-3, the main CPU 301 performs a pressing information storing process. Specifically, the main CPU 301 includes the left reel 18, the middle reel 19, the right reel 20 and the left stepping motor corresponding to the operated stop button among the left stop button 11, the middle stop button 12, and the right stop button 13. 151, based on the values of the pulse counters supplied to the middle stepping motor 152 and the right stepping motor 153, a process of acquiring the pressing reference position and storing it in the pressing reference position storage area provided in the main RAM 303 is performed. Then, when the process of step S113-3 ends, the process proceeds to step S113-4.

(Step S113-4)
In step S113-4, the main CPU 301 performs a sliding frame number acquisition process. Specifically, the main CPU 301 includes a stop table (not shown) provided in the main ROM 302, a drawing priority order, a winning combination determined by an internal lottery process, a left stop button 11, and a middle stop button 12. Then, based on the operation order of the right stop button 13 or the like, a process of acquiring the number of sliding frames is performed. Here, in the present embodiment, the main CPU 301 performs a process of determining the number of sliding frames within the range of “0” frames to “4” frames as the number of sliding frames. Then, when the process of step S113-4 ends, the process proceeds to step S113-5.

(Step S113-5)
In step S113-5, the main CPU 301 performs a reel stop process. Specifically, the main CPU 301 determines the reel based on the pressing reference position stored by the pressing information storing process of step S113-3 and the number of sliding frames acquired by the number of sliding frames acquired by step S113-4. Process to stop. Then, when the process of step S113-5 ends, the process proceeds to step S113-6.

(Step S113-6)
In step S113-6, the main CPU 301 performs processing for setting a reel stop command. Specifically, the main CPU 301 sets the reel stop command in the main transmission data storage area provided in the main RAM 303 in order to transmit the reel stop command to the payout board 350 and the sub-control board 400. Perform the process. Here, the “reel stop command” is a command having information such as a pressing reference position and the number of sliding frames. When the process of step S113-6 is completed, the subroutine for the reel rotation process is terminated, and the process proceeds to step S114 of the main loop process.

(Display judgment command reception standby processing)
Next, the display determination command reception standby process performed by the process of step S115 of FIG. 28 will be described based on FIG. FIG. 44 is a diagram showing a subroutine of display determination command reception standby processing.

(Step S115-1)
In step S115-1, the main CPU 301 performs a process of determining whether or not a display determination command has been received. Specifically, the main CPU 301 performs processing for determining whether or not a display determination command has been received from the payout board 350. More specifically, the main CPU 301 performs a process of determining whether information related to the display determination command is stored in a predetermined area of the main RAM 303. If it is determined that the display determination command has been received (step S115-1 = Yes), the process proceeds to step S115-2, and if it is determined that the display determination command has not been received ( In step S115-1 = No), the process of step S115-1 is repeatedly executed until a display determination command is received from the payout board 350.

(Step S115-2)
In step S115-2, the main CPU 301 performs a process of determining whether or not a symbol combination related to replay is displayed on the active line. Specifically, based on the display determination command received from the payout board 350, the main CPU 301 performs a process of determining whether or not a combination of symbols related to replay is displayed on the active line. If it is determined that the symbol combination related to replay is displayed on the active line (step S115-2 = Yes), the process proceeds to step S115-3, and the symbol combination related to replay is the active line. If it is determined that it is not displayed above (step S115-2 = No), the display determination command reception standby process subroutine is terminated, and the process proceeds to step S116 of the main loop process.

(Step S115-3)
In step S115-3, the main CPU 301 performs a process of turning on the re-game operating flag. Specifically, the main CPU 301 performs processing for turning on the value of the re-game operating flag storage area provided in the main RAM 303. When the process of step S115-3 is completed, the display determination command reception standby process subroutine is terminated, and the process proceeds to step S116 of the main loop process.

(Medal payout end command reception waiting process)
Next, based on FIG. 45, the medal payout end command reception standby process performed by the process of step S116 of FIG. 28 will be described. FIG. 45 is a diagram showing a subroutine of a medal payout end command reception standby process.

(Step S116-1)
In step S116-1, the main CPU 301 performs a process of determining whether or not a medal payout end command has been received. Specifically, the main CPU 301 performs a process of determining whether or not a medal payout end command has been received from the payout board 350. More specifically, the main CPU 301 performs processing for determining whether or not information relating to a medal payout end command is stored in a predetermined area of the main RAM 303. If it is determined that a medal payout end command has been received (step S116-1 = Yes), the medal payout end command reception waiting process subroutine is terminated, and the process proceeds to step S117 of the main loop process. On the other hand, when it is determined that the medal payout end command has not been received (step S116-1 = No), the process of step S116-1 is repeatedly executed until the medal payout end command is received from the payout board 350.

(Game state transition process)
Next, based on FIG. 46, the game state transition process performed by the process of step S117 of FIG. 28 will be described. 46 is a diagram showing a subroutine of the game state transition process.

(Step S117-1)
In step S117-1, the main CPU 301 performs processing to determine whether or not the gaming state is the second RT gaming state during BB. Specifically, the main CPU 301 determines whether or not the current gaming state is the second RT gaming state during BB based on the value stored in the gaming state storage area provided in the main RAM 303. I do. If it is determined that the gaming state is the second RT gaming state during BB (step S117-1 = Yes), the process proceeds to step S117-3, and the gaming state is not the second RT gaming state during BB. Is determined (step S117-1 = No), the process proceeds to step S117-2.

(Step S117-2)
In step S117-2, the main CPU 301 performs a process of determining whether or not the gaming state is the third RT gaming state during BB. Specifically, the main CPU 301 determines whether or not the current gaming state is the third RT gaming state during BB based on the value stored in the gaming state storage area provided in the main RAM 303. I do. If it is determined that the gaming state is the third RT gaming state during BB (step S117-2 = Yes), the process proceeds to step S117-3, and the gaming state is not the third RT gaming state during BB. (Step S117-2 = No), the process proceeds to step S117-4.

(Step S117-3)
In step S117-3, the main CPU 301 performs processing during BB operation, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the gaming state, etc., when “the combination of symbols relating to JAC” is displayed on the active line. When the process of step S117-3 is completed, the gaming state transition process subroutine is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-4)
In step S117-4, the main CPU 301 performs a process of determining whether or not the gaming state is the RB gaming state during the third RT. Specifically, the main CPU 301 determines whether or not the current gaming state is the third RB gaming state based on the value stored in the gaming state storage area provided in the main RAM 303. I do. If it is determined that the gaming state is the RB gaming state during the third RT (step S117-4 = Yes), the process proceeds to step S117-5, and the gaming state is not the RB gaming state during the third RT. Is determined (step S117-4 = No), the process proceeds to step S117-6.

(Step S117-5)
In step S117-5, the main CPU 301 performs processing during RB operation, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the gaming state based on the value of the winning number counter provided in the main RAM 303 or the value of the possible game number counter provided in the main RAM 303. When the process of step S117-5 is completed, the gaming state transition process subroutine is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-6)
In step S117-6, the main CPU 301 performs a process of determining whether or not a symbol combination related to the first RT gaming state transition replay is displayed on the active line. Specifically, the main CPU 301 determines whether or not the symbol combination related to the first RT gaming state transition replay is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. Process. When it is determined that the symbol combination related to the first RT gaming state transition replay is displayed on the active line (step S117-6 = Yes), the process proceeds to step S117-7, and the first RT gaming state If it is determined that the symbol combination related to the transition replay is not displayed on the active line (step S117-6 = No), the process proceeds to step S117-8.

(Step S117-7)
In step S117-7, the main CPU 301 performs processing for shifting the gaming state to the first RT gaming state. Specifically, the main CPU 301 performs processing for setting information relating to the first RT gaming state in a gaming state storage area provided in the main RAM 303. When the process of step S117-7 is completed, the gaming state transition process subroutine is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-8)
In step S117-8, the main CPU 301 performs a process of determining whether or not a combination of symbols related to the third RT gaming state transition replay is displayed on the active line. Specifically, the main CPU 301 determines whether or not the symbol combination related to the third RT gaming state transition replay is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. Process. If it is determined that the combination of symbols related to the third RT gaming state transition replay is displayed on the active line (step S117-8 = Yes), the process proceeds to step S117-9, and the third RT gaming state If it is determined that the symbol combination related to the transition replay is not displayed on the active line (step S117-8 = No), the process proceeds to step S117-10.

(Step S117-9)
In step S117-9, the main CPU 301 performs a process of shifting the gaming state to the non-BB third RT gaming state. Specifically, the main CPU 301 performs processing for setting information related to the third RT gaming state during non-BB in the gaming state storage area provided in the main RAM 303. When the process of step S117-9 is completed, the gaming state transition process subroutine is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-10)
In step S117-10, the main CPU 301 performs a process of determining whether or not a combination of symbols related to the fourth RT gaming state transition replay is displayed on the active line. Specifically, the main CPU 301 determines whether or not the symbol combination related to the fourth RT gaming state transition replay is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. Process. When it is determined that the symbol combination related to the 4RT gaming state transition replay is displayed on the active line (step S117-10 = Yes), the process proceeds to step S117-11, and the fourth RT gaming state is performed. If it is determined that the symbol combination related to the transition replay is not displayed on the active line (step S117-10 = No), the process proceeds to step S117-12.

(Step S117-11)
In step S117-11, the main CPU 301 performs processing for shifting the gaming state to the fourth RT gaming state. Specifically, the main CPU 301 performs processing for setting information related to the fourth RT gaming state in the gaming state storage area provided in the main RAM 303. When the process of step S117-11 is completed, the gaming state transition process subroutine is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-12)
In step S117-12, the main CPU 301 performs a process of determining whether or not the symbol combination related to BB is displayed on the active line. Specifically, the main CPU 301 performs a process of determining whether or not the combination of symbols related to BB is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. If it is determined that the symbol combination related to BB is displayed on the active line (step S117-12 = Yes), the process proceeds to step S117-13, and the symbol combination related to BB is the effective line. If it is determined that it is not displayed above (step S117-12 = No), the gaming state transition process subroutine is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-13)
In step S117-13, the main CPU 301 performs processing during BB operation. Specifically, the main CPU 301 performs processing for setting a predetermined value to the value of the payout number counter provided in the main RAM 303, processing for clearing the value of the carry flag storage area provided in the main RAM 303, and the like. Do. Here, the value of the payout number counter set in the BB operation process in step S117-13 can be set as appropriate. Then, when the process of step S117-13 ends, the process proceeds to step S117-14.

(Step S117-14)
In step S117-14, the main CPU 301 performs a process of shifting the gaming state to the second RT gaming state during BB. Specifically, the main CPU 301 performs processing for setting information related to the second RT gaming state during BB in the gaming state storage area provided in the main RAM 303. When the process of step S117-14 is completed, the gaming state transition process subroutine is terminated, and the process proceeds to step S118 of the main loop process.

(Process during BB operation)
Next, based on FIG. 47, the process during BB operation | movement performed by the process of step S117-3 of FIG. 46 is demonstrated. FIG. 47 is a diagram showing a subroutine of processing during BB operation.

(Step S117-3-1)
In step S117-3-1, the main CPU 301 performs a process of determining whether or not a symbol combination related to JAC is displayed on the active line. Specifically, the main CPU 301 performs a process of determining whether or not a combination of symbols related to JAC is displayed on the active line based on information related to the display determination command transmitted by the payout board 350. When it is determined that the combination of symbols related to JAC is displayed on the active line (step S117-3-1 = Yes), the process proceeds to step S117-3-2, and the symbol related to JAC is displayed. If it is determined that the combination is not displayed on the active line (step S117-3-1 = No), the process proceeds to step S117-3-5.

(Step S117-3-2)
In step S117-3-2, the main CPU 301 performs a process of shifting the gaming state to the RB gaming state during the third RT. Specifically, the main CPU 301 performs processing for setting information related to the third RT RB gaming state in the gaming state storage area provided in the main RAM 303. Then, when the process of step S117-3-2 ends, the process proceeds to step S117-3-3.

(Step S117-3-3)
In step S117-3-3, the main CPU 301 performs processing for clearing the carry flag storage area. Specifically, the main CPU 301 performs processing for clearing a carry flag storage area provided in the main RAM 303. Then, when the process of step S117-3-3 ends, the process proceeds to step S117-3-4.

(Step S117-3-4)
In step S117-3-4, the main CPU 301 performs counter setting processing. Specifically, the main CPU 301 performs a process of setting a predetermined value to the value of the winning number counter provided in the main RAM 303 and sets a predetermined value as the value of the game possible number counter provided in the main RAM 303. Perform processing to set. Here, the value of the winning number counter set in the counter setting process of step S117-3-4 and the value of the possible game number counter can be set as appropriate. Then, when the process of step S117-3-4 ends, the subroutine for the BB operation process ends, and the process proceeds to step S118 of the main loop process.

(Step S117-3-5)
In step S117-3-5, the main CPU 301 performs a payout number counter subtraction process. Specifically, the main CPU 301 determines the number of medals paid out to the player based on the information related to the medal payout end command transmitted from the payout board 350 from the value of the payout number counter provided in the main RAM 303. A process of subtracting the value of the number of sheets is performed. Then, when the process of step S117-3-5 ends, the process proceeds to step S117-3-6.

(Step S117-3-6)
In step S117-3-6, the main CPU 301 performs a process of determining whether or not the value of the payout number counter is less than “0”. Specifically, the main CPU 301 relates to the medal payout end command transmitted from the payout board 350 from the value of the payout number counter provided in the main RAM 303 by the payout number counter subtraction process in step S117-3-5. Based on the information, a process of determining whether or not the value of the payout number counter has become a negative value as a result of subtracting the value of the number of medals paid out to the player is performed. If it is determined that the value of the payout number counter is less than “0” (step S117-3-6 = Yes), the process proceeds to step S117-3-7, and the value of the payout number counter is If it is determined that it is not less than “0” (step S117-3-6 = No), the subroutine of the BB operation process is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-3-7)
In step S117-3-7, the main CPU 301 performs a process of determining whether or not the gaming state is the second RT gaming state during BB. Specifically, the main CPU 301 determines whether or not the current gaming state is the second RT gaming state during BB based on the value stored in the gaming state storage area provided in the main RAM 303. I do. If it is determined that the gaming state is the second RT gaming state during BB (step S117-3-7 = Yes), the process proceeds to step S117-3-8, and the gaming state is the second RT during BB. If it is determined that the game state is not set (step S117-3-7 = No), the process proceeds to step S117-3-9.

(Step S117-3-8)
In step S117-3-8, the main CPU 301 performs a process of shifting the gaming state to the non-BB second RT gaming state. Specifically, the main CPU 301 performs processing for setting information related to the second RT gaming state during non-BB in the gaming state storage area provided in the main RAM 303. Then, when the process of step S117-3-8 ends, the subroutine of the BB operation process ends, and the process proceeds to step S118 of the main loop process.

(Step S117-3-9)
In step S117-3-9, the main CPU 301 performs a process of shifting the gaming state to the non-BB third RT gaming state. Specifically, the main CPU 301 performs processing for setting information related to the third RT gaming state during non-BB in the gaming state storage area provided in the main RAM 303. When the process of step S117-3-9 ends, the subroutine for the BB operation process ends, and the process proceeds to step S118 of the main loop process.

(Processing during RB operation)
Next, based on FIG. 48, the process during RB operation | movement performed by the process of step S117-5 of FIG. 46 is demonstrated. FIG. 48 is a diagram showing a subroutine of processing during RB operation.

(Step S117-5-1)
In step S117-5-1, the main CPU 301 performs a process of subtracting “1” from the value of the possible game number counter. Specifically, the main CPU 301 performs a process of subtracting “1” from the value of the possible game number counter provided in the main RAM 303. Then, when the process of step S117-5-1 ends, the process proceeds to step S117-5-2.

(Step S117-5-2)
In step S117-5-2, the main CPU 301 performs a process of determining whether or not a winning is achieved. Specifically, the main CPU 301 performs a process of determining whether or not a combination of symbols related to winning is displayed on the active line based on information related to the display determination command transmitted by the payout board 350. If it is determined that a winning is achieved (step S117-5-2 = Yes), the process proceeds to step S117-5-3, and if it is determined that no winning is achieved ( Step S117-5-2 = No), the process proceeds to step S117-5-9.

(Step S117-5-3)
In step S117-5-3, the main CPU 301 performs a payout number counter subtraction process. Specifically, the main CPU 301 determines the number of medals paid out to the player based on the information related to the medal payout end command transmitted from the payout board 350 from the value of the payout number counter provided in the main RAM 303. A process of subtracting the value of the number of sheets is performed. Then, when the process of step S117-5-3 ends, the process proceeds to step S117-5-4.

(Step S117-5-4)
In step S117-5-4, the main CPU 301 performs a process of determining whether or not the value of the payout number counter is less than “0”. Specifically, the main CPU 301 relates to the medal payout end command transmitted from the payout board 350 from the value of the payout number counter provided in the main RAM 303 by the payout number counter subtraction process in step S117-5-3. Based on the information, a process of determining whether or not the value of the payout number counter has become a negative value as a result of subtracting the value of the number of medals paid out to the player is performed. If it is determined that the value of the payout number counter is less than “0” (step S117-5-4 = Yes), the process proceeds to step S117-5-5, and the value of the payout number counter is If it is determined that it is not less than “0” (step S117-5-4 = No), the process proceeds to step S117-5-6.

(Step S117-5-5)
In step S117-5-5, the main CPU 301 performs processing for shifting the gaming state to the non-RT gaming state. Specifically, the main CPU 301 performs processing for setting information related to a non-RT gaming state in a gaming state storage area provided in the main RAM 303. When the process of step S117-5-5 is completed, the subroutine of the RB operation process is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-5-6)
In step S117-5-6, the main CPU 301 performs a process of subtracting “1” from the value of the winning number counter. Specifically, the main CPU 301 performs a process of subtracting “1” from the value of the winning number counter provided in the main RAM 303. Then, when the process of step S117-5-6 ends, the process proceeds to step S117-5-7.

(Step S117-5-7)
In step S117-5-7, the main CPU 301 performs a process of determining whether or not the value of the winning number counter is “0”. Specifically, the main CPU 301 subtracts “1” from the value of the winning number counter provided in the main RAM 303 by the process of step S117-5-6, and as a result, the main CPU 301 sets the number of winning number counters provided in the main RAM 303. Processing for determining whether or not the value is “0” is performed. If it is determined that the value of the winning number counter is “0” (step S117-5-7 = Yes), the process proceeds to step S117-5-8, where the value of the winning number counter is “ If it is determined that it is not “0” (step S117-5-7 = No), the process proceeds to step S117-5-9.

(Step S117-5-8)
In step S117-5-8, the main CPU 301 performs a process of shifting the gaming state to the third RT gaming state during BB. Specifically, the main CPU 301 performs processing for setting information relating to the third RT gaming state during BB in the gaming state storage area provided in the main RAM 303. When the process of step S117-5-8 is completed, the subroutine of the RB operation process is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-5-9)
In step S117-5-9, the main CPU 301 performs a process of determining whether or not the value of the possible game number counter is “0”. Specifically, the main CPU 301 subtracts “1” from the value of the game possible number counter provided in the main RAM 303 by the process of step S117-5-1, and as a result, the number of possible games provided in the main RAM 303. Processing for determining whether or not the value of the counter is “0” is performed. If it is determined that the value of the game possible number counter is “0” (step S117-5-9 = Yes), the process proceeds to step S117-5-10, and the value of the game possible number counter is set. Is determined to be not “0” (step S117-5-9 = No), the subroutine of the RB operation process is terminated, and the process proceeds to step S118 of the main loop process.

(Step S117-5-10)
In step S117-5-10, the main CPU 301 performs a process of shifting the gaming state to the third RT gaming state during BB. Specifically, the main CPU 301 performs processing for setting information relating to the third RT gaming state during BB in the gaming state storage area provided in the main RAM 303. When the process of step S117-5-10 ends, the subroutine for the RB operation process ends, and the process proceeds to step S118 of the main loop process.

(Processing by display status)
Next, based on FIG. 49, the processing according to display state performed by the processing of step S118 of FIG. 28 will be described. FIG. 49 is a diagram showing a subroutine of processing by state at the time of display.

(Step S118-1)
In step S118-1, the main CPU 301 performs a process of determining whether or not the state number is “01”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “01”. When it is determined that the state number is “01” (step S118-1 = Yes), the process proceeds to step S118-2, and when it is determined that the state number is not “01”. (Step S118-1 = No), the process proceeds to Step S118-3.

(Step S118-2)
In step S118-2, the main CPU 301 performs a normal state process during display, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the ART ready state when the symbol combination related to the third RT gaming state transition replay is displayed on the active line. Then, when the process of step S118-2 is completed, the subroutine of the display state process is ended, and the process proceeds to step S101 of the main loop process.

(Step S118-3)
In step S118-3, the main CPU 301 performs a process of determining whether or not the state number is “02”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “02”. When it is determined that the state number is “02” (step S118-3 = Yes), the process proceeds to step S118-4, and when it is determined that the state number is not “02”. (Step S118-3 = No), the process proceeds to Step S118-5.

(Step S118-4)
In step S118-4, the main CPU 301 performs a display-time BB preparation state process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the BB state when the symbol combination related to BB is displayed on the active line. Then, when the process of step S118-4 is completed, the subroutine of the display state process is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-5)
In step S118-5, the main CPU 301 performs a process of determining whether or not the state number is “03”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “03”. When it is determined that the state number is “03” (step S118-5 = Yes), the process proceeds to step S118-6, and when it is determined that the state number is not “03”. (Step S118-5 = No), the process proceeds to Step S118-7.

(Step S118-6)
In step S118-6, the main CPU 301 performs a display-time BB state process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the RB state when a combination of symbols related to JAC is displayed on the active line. Then, when the process of step S118-6 is completed, the subroutine of the display time state process is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-7)
In step S118-7, the main CPU 301 performs processing for determining whether or not the state number is “04”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “04”. When it is determined that the state number is “04” (step S118-7 = Yes), the process proceeds to step S118-8, and when it is determined that the state number is not “04”. (Step S118-7 = No), the process proceeds to Step S118-9.

(Step S118-8)
In step S118-8, the main CPU 301 performs a display time RB state process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the normal state when the RB is finished and the BB is finished. Then, when the process of step S118-8 is completed, the subroutine for the display state process is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-9)
In step S118-9, the main CPU 301 performs processing for determining whether or not the state number is “05”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “05”. When it is determined that the state number is “05” (step S118-9 = Yes), the process proceeds to step S118-10, and when it is determined that the state number is not “05”. (Step S118-9 = No), the process proceeds to Step S118-11.

(Step S118-10)
In step S118-10, the main CPU 301 performs a display-time first fall standby state process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the normal state when the symbol combination related to the first RT gaming state transition replay is displayed on the active line. Then, when the process of step S118-10 is completed, the subroutine of the display state process is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-11)
In step S118-11, the main CPU 301 performs processing for determining whether or not the state number is “06”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “06”. When it is determined that the state number is “06” (step S118-11 = Yes), the process proceeds to step S118-12, and when it is determined that the state number is not “06”. (Step S118-11 = No), the process proceeds to Step S118-13.

(Step S118-12)
In step S118-12, the main CPU 301 performs a display-time ART preparation state process which will be described in detail later with reference to FIG. In the process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the ART state when a combination of symbols related to the fourth RT gaming state transition replay is displayed on the active line. Then, when the process of step S118-12 is completed, the subroutine of the display time state process is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-13)
In step S118-13, the main CPU 301 performs processing for determining whether or not the state number is “08”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “08”. When it is determined that the state number is “08” (step S118-13 = Yes), the process proceeds to step S118-14, and when it is determined that the state number is not “08”. (Step S118-13 = No), the process proceeds to Step S118-15.

(Step S118-14)
In step S118-14, the main CPU 301 performs a BB preparation state process during ART during display, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the BB state during ART when the combination of symbols related to BB is displayed on the active line. Then, when the process of step S118-14 is completed, the subroutine of the display time state process is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-15)
In step S118-15, the main CPU 301 performs a process of determining whether or not the state number is “09”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “09”. When it is determined that the state number is “09” (step S118-15 = Yes), the process proceeds to step S118-16, and when it is determined that the state number is not “09”. (Step S118-15 = No), the process proceeds to Step S118-17.

(Step S118-16)
In step S118-16, the main CPU 301 performs processing for the BB state during ART during display, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the RB state during ART when the combination of symbols related to JAC is displayed on the active line. When the process of step S118-16 is completed, the subroutine for the display state process is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-17)
In step S118-17, the main CPU 301 performs processing for determining whether or not the state number is “10”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “10”. When it is determined that the state number is “10” (step S118-17 = Yes), the process proceeds to step S118-18, and when it is determined that the state number is not “10”. (Step S118-17 = No), the process proceeds to Step S118-19.

(Step S118-18)
In step S118-18, the main CPU 301 performs processing for the RB state during ART during display, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the ART state when the RB ends and the BB ends. Then, when the process of step S118-18 is completed, the subroutine of the display time state process is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-19)
In step S118-19, the main CPU 301 performs processing for determining whether or not the state number is “11”. Specifically, the main CPU 301 performs a process of determining whether or not the value stored in the state number storage area provided in the main RAM 303 is “11”. When it is determined that the state number is “11” (step S118-19 = Yes), the process proceeds to step S118-20, and when it is determined that the state number is not “11”. (Step S118-19 = No), the subroutine for the state process at the time of display ends, and the process proceeds to Step S101 of the main loop process.

(Step S118-20)
In step S118-20, the main CPU 301 performs a display-time second fall standby state process which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of shifting the state managed by the main control board 300 to the normal state when the symbol combination related to the first RT gaming state transition replay is displayed on the active line. Then, when the process of step S118-20 is completed, the subroutine for the display state process is terminated, and the process proceeds to step S101 of the main loop process.

(Processing for normal state during display)
Next, the display normal state process performed by the process of step S118-2 of FIG. 49 will be described based on FIG. FIG. 50 is a diagram showing a subroutine for normal state processing at the time of display.

(Step S118-2-1)
In step S118-2-1, the main CPU 301 performs a process of determining whether or not a combination of symbols related to the third RT gaming state transition replay is displayed on the active line. Specifically, the main CPU 301 determines whether or not the symbol combination related to the third RT gaming state transition replay is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. Process. If it is determined that the combination of symbols related to the third RT gaming state transition replay is displayed on the active line (step S118-2-1 = Yes), the process proceeds to step S118-2-2, If it is determined that the combination of symbols related to the third RT gaming state transition replay is not displayed on the active line (step S118-2-1 = No), the display normal state processing subroutine is terminated, The process proceeds to step S101 of the main loop process.

(Step S118-2-2)
In step S118-2-2, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the ART preparation state. Specifically, the main CPU 301 performs processing for setting information relating to the ART preparation state in a state storage area provided in the main RAM 303. When the process of step S118-2-2 ends, the display normal state process subroutine ends, and the process proceeds to step S101 of the main loop process.

(Process for BB preparation state at the time of display)
Next, the display-time BB preparation state process performed by the process of step S118-4 of FIG. 49 will be described with reference to FIG. FIG. 51 is a diagram showing a subroutine for the display-time BB preparation state process.

(Step S118-4-1)
In step S118-4-1, the main CPU 301 performs a process of determining whether or not the symbol combination related to BB is displayed on the active line. Specifically, the main CPU 301 performs a process of determining whether or not the combination of symbols related to BB is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. And when it determines with the combination of the symbol which concerns on BB being displayed on the effective line (step S118-4-1 = Yes), it transfers a process to step S118-4-2, When it is determined that the combination is not displayed on the active line (step S118-4-1 = No), the display time BB preparation state processing subroutine is terminated, and the processing is advanced to step S101 of the main loop processing. Transition.

(Step S118-4-2)
In step S118-4-2, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the BB state. Specifically, the main CPU 301 performs processing for setting information relating to the BB state in a state storage area provided in the main RAM 303. When the process of step S118-4-2 ends, the subroutine for the display-time BB preparation state process ends, and the process proceeds to step S101 of the main loop process.

(Process for BB state during display)
Next, the display-time BB state process performed by the process of step S118-6 in FIG. 49 will be described with reference to FIG. FIG. 52 is a diagram showing a subroutine of processing for the display BB state.

(Step S118-6-1)
In step S118-6-1, the main CPU 301 performs a process of determining whether or not a combination of symbols related to JAC is displayed on the active line. Specifically, the main CPU 301 performs a process of determining whether or not a combination of symbols related to JAC is displayed on the active line based on information related to the display determination command transmitted by the payout board 350. If it is determined that the combination of symbols related to JAC is displayed on the active line (step S118-6-1 = Yes), the process proceeds to step S118-6-2, and the symbol related to JAC is displayed. If it is determined that the combination is not displayed on the active line (step S118-6-1 = No), the process proceeds to step S118-6-3.

(Step S118-6-2)
In step S118-6-2, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the RB state. Specifically, the main CPU 301 performs processing for setting information related to the RB state in a state storage area provided in the main RAM 303. When the process of step S118-6-2 ends, the subroutine for the display-time BB state ends, and the process proceeds to step S101 of the main loop process.

(Step S118-6-3)
In step S118-6-3, the main CPU 301 performs a process of determining whether or not it is the BB end time. Specifically, the main CPU 301 performs a process of determining whether or not it is at the end of the BB based on the value of the payout number counter provided in the main RAM 303. Here, in this embodiment, when the value of the payout number counter becomes a negative value, the BB is ended. If it is determined that the BB is finished (step S118-6-3 = Yes), the process proceeds to step S118-6-4. If it is determined that the BB is not finished ( In step S118-6-3 = No), the display time BB state processing subroutine is terminated, and the process proceeds to step S101 of the main loop processing.

(Step S118-6-4)
In step S118-6-4, the main CPU 301 performs processing for determining whether or not the ART winning flag is ON. Specifically, the main CPU 301 performs processing for determining whether or not the ART winning flag is ON based on the value stored in the ART winning flag storage area provided in the main RAM 303. If it is determined that the ART winning flag is ON (step S118-6-4 = Yes), the process proceeds to step S118-6-5, and it is determined that the ART winning flag is not ON. In this case (step S118-6-4 = No), the process proceeds to step S118-6-7.

(Step S118-6-5)
In step S118-6-5, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the ART preparation state. Specifically, the main CPU 301 performs processing for setting information relating to the ART preparation state in a state storage area provided in the main RAM 303. Then, when the process of step S118-6-5 ends, the process proceeds to step S118-6-6.

(Step S118-6-6)
In step S118-6-6, the main CPU 301 performs processing for turning off the ART winning flag. Specifically, the main CPU 301 performs processing for turning off the ART winning flag in the ART winning flag storage area provided in the main RAM 303. When the process of step S118-6-6 ends, the subroutine for the display BB state process ends, and the process proceeds to step S101 of the main loop process.

(Step S118-6-7)
In step S118-6-7, the main CPU 301 performs a process of setting the state managed by the main control board 300 to the first fall standby state. Specifically, the main CPU 301 performs processing for setting information related to the first fall standby state in a state storage area provided in the main RAM 303. When the process of step S118-6-7 is completed, the subroutine for the display BB state process is terminated, and the process proceeds to step S101 of the main loop process.

(Process for RB state during display)
Next, the display-time RB state process performed by the process of step S118-8 of FIG. 49 will be described based on FIG. FIG. 53 is a diagram showing a subroutine of the display-time RB state process.

(Step S118-8-1)
In step S <b> 118-8-1, the main CPU 301 performs a process for determining whether or not it is the end of the RB. Specifically, the main CPU 301 determines whether or not it is the end of the RB based on the value of the winning number counter provided in the main RAM 303 or the value of the possible game number counter provided in the main RAM 303. Perform the process. If it is determined that the RB is finished (step S118-8-1 = Yes), the process proceeds to step S118-8-2. If it is determined that the RB is not finished ( Step S118-8-1 = No), the display time RB state processing subroutine is terminated, and the process proceeds to Step S101 of the main loop processing.

(Step S118-8-2)
In step S118-8-2, the main CPU 301 performs a process of determining whether or not it is the BB end time. Specifically, the main CPU 301 performs a process of determining whether or not it is at the end of the BB based on the value of the payout number counter provided in the main RAM 303. If it is determined that the BB is finished (step S118-8-2 = Yes), the process proceeds to step S118-8-3. If it is determined that the BB is not finished ( Step S118-8-2 = No) and the process proceeds to Step S118-8-4.

(Step S118-8-3)
In step S118-8-3, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the normal state. Specifically, the main CPU 301 performs processing for setting information related to a normal state in a state storage area provided in the main RAM 303. When the process of step S118-8-3 is completed, the subroutine for display RB state processing is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-8-4)
In step S118-8-4, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the BB state. Specifically, the main CPU 301 performs processing for setting information relating to the BB state in a state storage area provided in the main RAM 303. When the process of step S118-8-4 is completed, the subroutine for display RB state processing is terminated, and the process proceeds to step S101 of the main loop process.

(Processing for the first fall standby state during display)
Next, based on FIG. 54, the display first fall standby state process performed by the process of step S118-10 of FIG. 49 will be described. FIG. 54 is a diagram showing a subroutine of the first fall standby state process during display.

(Step S118-10-1)
In step S118-10-1, the main CPU 301 performs a process of determining whether or not a symbol combination related to the first RT gaming state transition replay is displayed on the active line. Specifically, the main CPU 301 determines whether or not the symbol combination related to the first RT gaming state transition replay is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. Process. If it is determined that the symbol combination related to the first RT gaming state transition replay is displayed on the active line (step S118-10-1 = Yes), the process proceeds to step S118-10-2. When it is determined that the combination of symbols related to the first RT gaming state transition replay is not displayed on the active line (step S118-10-1 = No), the subroutine for the first fall standby state process at the time of display is performed. The process ends, and the process proceeds to step S101 of the main loop process.

(Step S118-10-2)
In step S118-10-2, the main CPU 301 performs a process for changing the state managed by the main control board 300 to the normal state. Specifically, the main CPU 301 performs processing for setting information related to a normal state in a state storage area provided in the main RAM 303. Then, when the process of step S118-10-2 is completed, the subroutine for the first falling standby state process at the time of display ends, and the process proceeds to step S101 of the main loop process.

(Processing for ART preparation state at the time of display)
Next, the display-time ART preparation state process performed by the process of step S118-12 of FIG. 49 will be described with reference to FIG. FIG. 55 is a diagram showing a subroutine of display time ART preparation state processing.

(Step S118-12-1)
In step S118-12-1, the main CPU 301 performs a process of determining whether or not a combination of symbols related to the fourth RT gaming state transition replay is displayed on the active line. Specifically, the main CPU 301 determines whether or not the symbol combination related to the fourth RT gaming state transition replay is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. Process. And when it determines with the combination of the symbol which concerns on 4th RT game state transfer replay being displayed on the active line (step S118-12-1 = Yes), it transfers a process to step S118-12-2, When it is determined that the combination of symbols related to the fourth RT gaming state transition replay is not displayed on the active line (step S118-12-1 = No), the subroutine for the display-time ART ready state process is terminated. Then, the process proceeds to step S101 of the main loop process.

(Step S118-12-2)
In step S118-12-2, the main CPU 301 performs an ART state game number counter addition process. Specifically, the main CPU 301 performs processing for setting the value of the ART state game number counter provided in the main RAM 303. Here, in the present embodiment, the main CPU 301 sets the value of the ART state game number counter provided in the main RAM 303 when the state shifts to the ART ready state after the ART BB state ends. In a normal state, a direct hit replay is won by an internal lottery process, and after a combination of symbols relating to the third RT gaming state transition replay is displayed on the active line, the symbol relating to the fourth RT gaming state transition replay is displayed. When the combination is displayed on the active line or in the BB state, after winning the BB ART state transition lottery process in step S106-4-2, the state transitions to the ART ready state and relates to the fourth RT gaming state transition replay. The AR provided in the main RAM 303 when the combination of symbols is displayed on the active line It performs a process to set the value of the state game number counter for. That is, the process of setting the value of the ART state game number counter provided in the main RAM 303 is a process performed at the so-called “first win”. Then, when the process of step S118-12-2 ends, the process proceeds to step S118-12-3.

(Step S118-12-3)
In step S118-12-3, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the ART state. Specifically, the main CPU 301 performs processing for setting information relating to the ART state in a state storage area provided in the main RAM 303. When the process of step S118-12-3 is completed, the subroutine for the display-time ART preparation state process is terminated, and the process proceeds to step S101 of the main loop process.

(Process for BB preparation status during ART during display)
Next, based on FIG. 56, the processing for the BB preparation state during ART during display performed by the processing of step S118-14 of FIG. 49 will be described. FIG. 56 is a diagram showing a subroutine of processing for the BB preparation state during ART during display.

(Step S118-14-1)
In step S118-14-1, the main CPU 301 performs a process of determining whether or not the symbol combination related to BB is displayed on the active line. Specifically, the main CPU 301 performs a process of determining whether or not the combination of symbols related to BB is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. And when it determines with the combination of the symbol which concerns on BB being displayed on the effective line (step S118-14-1 = Yes), it transfers a process to step S118-14-2, If it is determined that the combination is not displayed on the active line (step S118-14-1 = No), the subroutine for the BB preparation state process during the ART at the time of display is terminated, and the process proceeds to step S101 of the main loop process. Migrate processing.

(Step S118-14-2)
In step S118-14-2, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the BB state during ART. Specifically, the main CPU 301 performs processing for setting information related to the BB state during ART in a state storage area provided in the main RAM 303. When the process of step S118-14-2 is completed, the subroutine for the BB preparation state process during ART during display is ended, and the process proceeds to step S101 of the main loop process.

(Process for BB state during ART during display)
Next, the processing for the BB state during ART during display performed by the processing of step S118-16 of FIG. 49 will be described based on FIG. FIG. 57 is a diagram showing a subroutine of processing for the BB state during ART during display.

(Step S118-16-1)
In step S118-16-1, the main CPU 301 performs a process of determining whether or not a combination of symbols related to JAC is displayed on the active line. Specifically, the main CPU 301 performs a process of determining whether or not a combination of symbols related to JAC is displayed on the active line based on information related to the display determination command transmitted by the payout board 350. If it is determined that the combination of symbols related to JAC is displayed on the active line (step S118-16-1 = Yes), the process proceeds to step S118-16-2, and the symbol related to JAC is displayed. If it is determined that the combination is not displayed on the active line (step S118-16-1 = No), the process proceeds to step S118-16-3.

(Step S118-16-2)
In step S118-16-2, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the RB state during ART. Specifically, the main CPU 301 performs processing for setting information related to the RB state during ART in a state storage area provided in the main RAM 303. When the process of step S118-16-2 is completed, the subroutine for the BB state process during ART during display is terminated, and the process proceeds to step S101 of the main loop process.

(Step S118-16-3)
In step S118-16-3, the main CPU 301 performs a process of determining whether or not it is the BB end time. Specifically, the main CPU 301 performs a process of determining whether or not it is at the end of the BB based on the value of the payout number counter provided in the main RAM 303. If it is determined that the BB is finished (step S118-16-3 = Yes), the process proceeds to step S118-16-4. If it is determined that the BB is not finished ( Step S118-16-3 = No), the subroutine for the BB state process during ART during display is ended, and the process proceeds to Step S101 of the main loop process.

(Step S118-16-4)
In step S118-16-4, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the ART preparation state. Specifically, the main CPU 301 performs processing for setting information relating to the ART preparation state in a state storage area provided in the main RAM 303. When the process of step S118-16-4 is completed, the subroutine for the BB state process during ART during display is ended, and the process proceeds to step S101 of the main loop process.

(Process for RB state during ART during display)
Next, the processing for the RB state during ART during display performed by the processing of step S118-18 in FIG. 49 will be described based on FIG. FIG. 58 is a diagram showing a subroutine for the RB state processing during ART during display.

(Step S118-18-1)
In step S118-18-1, the main CPU 301 performs a process of determining whether or not it is the RB end time. Specifically, the main CPU 301 determines whether or not it is the end of the RB based on the value of the winning number counter provided in the main RAM 303 or the value of the possible game number counter provided in the main RAM 303. Perform the process. If it is determined that the RB is finished (step S118-18-1 = Yes), the process proceeds to step S118-18-2. If it is determined that the RB is not finished ( Step S118-18-1 = No), the subroutine for the RB state process during ART during display is terminated, and the process proceeds to Step S101 of the main loop process.

(Step S118-18-2)
In step S118-18-2, the main CPU 301 performs a process of determining whether or not it is the BB end time. Specifically, the main CPU 301 performs a process of determining whether or not it is at the end of the BB based on the value of the payout number counter provided in the main RAM 303. If it is determined that the time is BB end (step S118-18-2 = Yes), the process proceeds to step S118-18-3. If it is determined that the time is not BB ( The process proceeds to step S118-18-2 = No) and step S118-18-4.

(Step S118-18-3)
In step S118-18-3, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the ART state. Specifically, the main CPU 301 performs processing for setting information relating to the ART state in a state storage area provided in the main RAM 303. When the process of step S118-18-3 is completed, the subroutine for the RB state process during ART during display is ended, and the process proceeds to step S101 of the main loop process.

(Step S118-18-4)
In step S118-18-4, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the BB state during ART. Specifically, the main CPU 301 performs processing for setting information related to the BB state during ART in a state storage area provided in the main RAM 303. Then, when the process of step S118-18-4 is completed, the subroutine for the display RB state process is terminated, and the process proceeds to step S101 of the main loop process.

(Processing for the second fall standby state during display)
Next, the display-time second fall standby state process performed by the process of step S118-20 of FIG. 49 will be described based on FIG. FIG. 59 is a diagram showing a subroutine of the second fall standby state process during display.

(Step S118-20-1)
In step S118-20-1, the main CPU 301 performs a process of determining whether or not a symbol combination related to the first RT gaming state transition replay is displayed on the active line. Specifically, the main CPU 301 determines whether or not the symbol combination related to the first RT gaming state transition replay is displayed on the active line based on the information related to the display determination command transmitted by the payout board 350. Process. When it is determined that the symbol combination related to the first RT gaming state transition replay is displayed on the active line (step S118-20-1 = Yes), the process proceeds to step S118-20-2. When it is determined that the combination of symbols related to the first RT gaming state transition replay is not displayed on the active line (step S118-20-1 = No), the subroutine for the second fall standby state process at the time of display is executed. The process ends, and the process proceeds to step S101 of the main loop process.

(Step S118-20-2)
In step S118-20-2, the main CPU 301 performs processing for changing the state managed by the main control board 300 to the normal state. Specifically, the main CPU 301 performs processing for setting information related to a normal state in a state storage area provided in the main RAM 303. Then, when the process of step S118-20-2 is completed, the subroutine for the second fall-down state at the time of display is terminated, and the process proceeds to step S101 of the main loop process.

(Interrupt processing)
Next, the interrupt process will be described with reference to FIG. Here, the interrupt process is a process performed by interrupting the main loop process every “1.49 ms”.

(Step S201)
In step S <b> 201, the main CPU 301 performs processing for saving a register. Specifically, the main CPU 301 performs processing for saving the value of the register used at the time of step S201. Then, when the process of step S201 ends, the process proceeds to step S202.

(Step S202)
In step S202, the main CPU 301 performs input port reading processing, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs BET switch input signal, MAXBET switch input signal, start switch input signal, left stop switch input signal, middle stop switch input signal, right stop switch input signal, auxiliary storage sensor input signal, door open / close Performs processing when a sensor input signal is input. Then, when the process of step S202 ends, the process proceeds to step S203.

(Step S203)
In step S203, the main CPU 301 performs an external signal output data set process. Specifically, the main CPU 301 performs processing for setting output port data of the external concentration terminal board 46 when there is an output request for an external signal related to an error. Then, when the process of step S203 ends, the process proceeds to step S204.

(Step S204)
In step S204, the main CPU 301 performs a timer measurement process. Specifically, the main CPU 301 performs a process of subtracting “1” from the value of the timer for effect at the time of the spinning effect and the value of the timer counter for measuring the minimum game time and the like. Then, when the process of step S204 ends, the process proceeds to step S205.

(Step S205)
In step S205, the main CPU 301 performs a process of setting “3” as the reel number. Specifically, the main CPU 301 performs a process of setting “3” as the reel number in order to set the target of the reel to be driven and controlled in the reel drive control process of step S206 described later. Then, when the process of step S205 ends, the process proceeds to step S206.

(Step S206)
In step S206, the main CPU 301 performs a reel drive control process. Specifically, the main CPU 301 via the reel control board 150, the reel number set by the process of step S205 or the left reel 18 corresponding to the reel number set by the process of step S207 described later, By driving the left stepping motor 151, the middle stepping motor 152, and the right stepping motor 153 of the reel 19, the right reel 20, rotation acceleration, constant speed, deceleration control, etc. of the left reel 18, the middle reel 19, and the right reel 20 are controlled. Do. Then, when the process of step S206 ends, the process proceeds to step S207.

  In this embodiment, the main CPU 301 performs drive control of the right reel 20 when the reel number is “3”, and performs drive control of the middle reel 19 when the reel number is “2”. When the reel number is “1”, drive control of the left reel 18 is performed.

(Step S207)
In step S207, the main CPU 301 performs a process of subtracting “1” from the reel number. Specifically, the main CPU 301 performs a process of subtracting “1” from the reel number currently set in the register. Then, when the process of step S207 ends, the process proceeds to step S208.

(Step S208)
In step S208, the main CPU 301 performs a process of determining whether or not the reel number is “0”. Specifically, the main CPU 301 performs a process of determining whether or not the reel drive control process of step S206 has been performed for all the reels of the left reel 18, the middle reel 19, and the right reel 20. When it is determined that the reel number is “0” (step S208 = Yes), the process proceeds to step S209, and when it is determined that the reel number is not “0” (step S208). = No), the process proceeds to step S206.

(Step S209)
In step S209, the main CPU 301 performs an external signal output process. In this processing, the main CPU 301 performs processing for setting output port data of the external concentration terminal board 46 and the like. Then, when the process of step S209 ends, the process proceeds to step S210.

(Step S210)
In step S210, the main CPU 301 performs control command reception processing, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of storing information included in the command received from the payout board 350 in the main RAM 303. Then, when the process of step S210 ends, the process proceeds to step S211.

(Step S211)
In step S211, the main CPU 301 performs control command transmission processing, which will be described in detail later with reference to FIG. In this process, the main CPU 301 performs a process of transmitting various commands to the payout board 350 and the sub control board 400. Then, when the process of step S211 is completed, the process proceeds to step S212.

(Step S212)
In step S212, the main CPU 301 performs LED output data creation processing. Specifically, the main CPU 301 includes a start lamp 24, a first BET lamp 25, a second BET lamp 26, a third BET lamp 27, a stored number display 28, a payout number display 29, a throwable display lamp 30, and a replay display. Processing for creating display data of the lamp 31 is performed. Then, when the process of step S212 ends, the process proceeds to step S213.

(Step S213)
In step S213, the main CPU 301 performs LED display processing. Specifically, the main CPU 301 includes a start lamp 24, a first BET lamp 25, a second BET lamp 26, a third BET lamp 27, a stored number display 28, a payout number display 29, a throwable display lamp 30, and a replay display. The lamp 31 is controlled. Then, when the process of step S213 ends, the process proceeds to step S214.

  Here, based on the command received from the payout board 350, the main CPU 301 controls the stored number display 28, the payout number display 29, and the like. Specifically, the main CPU 301 performs control to turn on the first BET lamp 25, the second BET lamp 26, and the third BET lamp 27 when a medal automatic insertion command described later is received from the payout board 350. When the main CPU 301 receives a settlement start command (described later) from the payout board 350, the main CPU 301 performs a process of subtracting the stored number displayed on the stored number display 28 and receives a settlement end command (described later). In this case, a process for terminating the subtraction display of the stored number display 28 is performed.

  When the main CPU 301 receives a medal insertion command (to be described later) from the payout board 350, the main CPU 301 performs a process of adding and displaying the stored number displayed on the stored number display 28. When the main CPU 301 receives a later-described BET command from the payout board 350, the main CPU 301 performs a process of subtracting and displaying the stored number displayed on the stored number display 28.

  When the main CPU 301 receives a medal payout start command (to be described later) or a medal payout end command (to be described later) from the payout board 350, the main CPU 301 performs a process of adding and displaying the stored number displayed on the stored number display 28. At the same time, a process of displaying the number of payouts on the payout number display 29 is performed. When the main CPU 301 receives a medal insertion error command (to be described later) or an illegal hit command (to be described later) from the payout board 350, the main CPU 301 performs an error display process on the payout number display 29.

(Step S214)
In step S214, the main CPU 301 performs port output processing. Specifically, the main CPU 301 performs a process of transmitting a predetermined signal to the status board 100, the reel control board 150, the power supply board 200, and the sub control board 400. Then, when the process of step S214 ends, the process proceeds to step S215.

(Step S215)
In step S215, the main CPU 301 performs a register restoration process. Specifically, the main CPU 301 performs a process of restoring the saved register value in the process of step S201. Then, when the process of step S215 ends, the interrupt process ends, and the process returns to the main loop process.

(Input port read processing)
Next, the input port reading process performed by the process of step S202 of FIG. 60 will be described based on FIG. FIG. 61 is a diagram showing a subroutine of input port read processing.

(Step S202-1)
In step S202-1, the main CPU 301 performs processing for determining whether or not a BET switch input signal has been received. Specifically, the main CPU 301 performs processing for determining whether or not a BET switch input signal has been received from the status board 100. Here, the status board 100 performs a process of transmitting a BET switch input signal to the main control board 300 when the BET switch 7 sw detects an operation of the BET button 7. When it is determined that the BET switch input signal has been received (step S202-1 = Yes), the process proceeds to step S202-2, and when it is determined that the BET switch input signal has not been received. (Step S202-1 = No), the process proceeds to Step S202-3.

(Step S202-2)
In step S202-2, the main CPU 301 performs processing for determining that the BET switch has been turned ON. Specifically, the main CPU 301 performs processing for setting information indicating that the BET switch 7 sw is turned on in a predetermined area of the main RAM 303. When the process of step S202-2 ends, the input port read process subroutine ends, and the process proceeds to step S203 of the interrupt process.

(Step S202-3)
In step S202-3, the main CPU 301 performs processing for determining whether or not a MAXBET switch input signal has been received. Specifically, the main CPU 301 performs processing for determining whether or not a MAXBET switch input signal has been received from the status board 100. Here, the status board 100 performs processing of transmitting a MAXBET switch input signal to the main control board 300 when the MAXBET switch 8sw detects the operation of the MAXBET button 8. If it is determined that the MAXBET switch input signal has been received (step S202-3 = Yes), the process proceeds to step S202-4, and if it is determined that the MAXBET switch input signal has not been received. (Step S202-3 = No), the process proceeds to Step S202-5.

(Step S202-4)
In step S202-4, the main CPU 301 performs processing for determining that the MAXBET switch is turned on. Specifically, the main CPU 301 performs processing for setting information indicating that the MAXBET switch 8sw is turned on in a predetermined area of the main RAM 303. When the process of step S202-4 is completed, the input port reading process subroutine is terminated, and the process proceeds to step S203 of the interrupt process.

(Step S202-5)
In step S202-5, the main CPU 301 performs processing for determining whether or not a start switch input signal has been received. Specifically, the main CPU 301 performs processing for determining whether a start switch input signal is received from the status board 100. Here, the status board 100 performs a process of transmitting a start switch input signal to the main control board 300 when the start switch 10 sw detects the operation of the start lever 10. When it is determined that the start switch input signal has been received (step S202-5 = Yes), the process proceeds to step S202-6, and when it is determined that the start switch input signal has not been received. (Step S202-5 = No), the process proceeds to Step S202-7.

(Step S202-6)
In step S202-6, the main CPU 301 performs processing for determining that the start switch has been turned ON. Specifically, the main CPU 301 performs processing for setting information indicating that the start switch 10 sw is turned on in a predetermined area of the main RAM 303. When the process of step S202-6 ends, the input port read process subroutine ends, and the process proceeds to interrupt process step S203.

(Step S202-7)
In step S202-7, the main CPU 301 performs processing for determining whether or not a left stop switch input signal has been received. Specifically, the main CPU 301 performs a process of determining whether or not a left stop switch input signal has been received from the status board 100. Here, the status board 100 performs a process of transmitting a left stop switch input signal to the main control board 300 when the left stop switch 11sw detects an operation of the left stop button 11. If it is determined that the left stop switch input signal has been received (step S202-7 = Yes), the process proceeds to step S202-8, and it is determined that the left stop switch input signal has not been received. In this case (step S202-7 = No), the process proceeds to step S202-9.

(Step S202-8)
In step S202-8, the main CPU 301 performs processing for determining that the left stop switch has been turned ON. Specifically, the main CPU 301 performs processing for setting information indicating that the left stop switch 11sw is turned on in a predetermined area of the main RAM 303. When the process of step S202-8 ends, the input port reading process subroutine ends, and the process proceeds to step S203 of the interrupt process.

(Step S202-9)
In step S202-9, the main CPU 301 performs a process of determining whether or not an intermediate stop switch input signal has been received. Specifically, the main CPU 301 performs processing for determining whether or not an intermediate stop switch input signal has been received from the status board 100. Here, the status board 100 performs processing of transmitting an intermediate stop switch input signal to the main control board 300 when the intermediate stop switch 12sw detects an operation of the intermediate stop button 12. If it is determined that the intermediate stop switch input signal has been received (step S202-9 = Yes), the process proceeds to step S202-10, and it is determined that the intermediate stop switch input signal has not been received. In that case (step S202-9 = No), the process proceeds to step S202-11.

(Step S202-10)
In step S202-10, the main CPU 301 performs processing for determining that the middle stop switch has been turned ON. Specifically, the main CPU 301 performs processing for setting information indicating that the middle stop switch 12sw is turned ON in a predetermined area of the main RAM 303. When the process of step S202-10 ends, the input port read process subroutine ends, and the process proceeds to interrupt process step S203.

(Step S202-11)
In step S202-11, the main CPU 301 performs a process of determining whether or not a right stop switch input signal has been received. Specifically, the main CPU 301 performs a process of determining whether or not a right stop switch input signal has been received from the status board 100. Here, the status board 100 performs a process of transmitting a right stop switch input signal to the main control board 300 when the right stop switch 13sw detects an operation of the right stop button 13. When it is determined that the right stop switch input signal has been received (step S202-11 = Yes), the process proceeds to step S202-12, and it is determined that the right stop switch input signal has not been received. In that case (step S202-11 = No), the process proceeds to step S202-13.

(Step S202-12)
In step S202-12, the main CPU 301 performs processing for determining that the right stop switch has been turned ON. Specifically, the main CPU 301 performs processing for setting information indicating that the right stop switch 13sw is turned on in a predetermined area of the main RAM 303. When the process of step S202-12 ends, the input port reading process subroutine ends, and the process proceeds to step S203 of the interrupt process.

(Step S202-13)
In step S202-13, the main CPU 301 performs processing for determining whether or not an auxiliary storage sensor input signal has been received. Specifically, the main CPU 301 performs processing for determining whether or not an auxiliary storage sensor input signal is received from the status board 100. Here, the status board 100 sends an auxiliary storage sensor input signal to the main control board 300 when the auxiliary storage sensor 203s detects that the medals stored in the auxiliary storage 203 are full. Process to send. If it is determined that the auxiliary storage sensor input signal has been received (step S202-13 = Yes), the process proceeds to step S202-14, and it is determined that the auxiliary storage sensor input signal has not been received. If it is determined (step S202-13 = No), the process proceeds to step S202-15.

(Step S202-14)
In step S202-14, the main CPU 301 performs processing for determining that the auxiliary storage sensor is turned on. Specifically, the main CPU 301 performs processing for setting information indicating that the auxiliary storage sensor 203s is turned on in a predetermined area of the main RAM 303. When the process of step S202-14 ends, the input port read process subroutine ends, and the process proceeds to step S203 of the interrupt process.

(Step S202-15)
In step S202-15, the main CPU 301 performs a process of determining whether or not a door opening / closing sensor input signal has been received. Specifically, the main CPU 301 performs processing for determining whether or not a door opening / closing sensor input signal has been received from the status board 100. Here, the status board 100 is the main control board when the door opening / closing sensor 17s detects that the front door 3 is opened, or when the door opening / closing sensor 17s detects that the front door 3 is closed. A process of transmitting a door open / close sensor input signal to 300 is performed. If it is determined that the door open / close sensor input signal has been received (step S202-15 = Yes), the process proceeds to step S202-16, and it is determined that the door open / close sensor input signal has not been received. In this case (step S202-15 = No), the input port reading process subroutine is terminated, and the process proceeds to step S203 of the interrupt process.

(Step S202-16)
In step S202-16, the main CPU 301 performs a door opening / closing sensor ON / OFF switching process. Specifically, the main CPU 301 performs a process of rewriting a predetermined area of the main RAM 303 in which information indicating that the door opening / closing sensor 17s is turned on is set. More specifically, a door open / close sensor input signal having information indicating that the front door 3 is closed is stored in a predetermined area of the main RAM 303. Is received, a process for storing information indicating that the front door 3 is closed in a predetermined area of the main RAM 303 is performed, and information indicating that the front door 3 is closed in a predetermined area of the main RAM 303. Is stored, and when a door open / close sensor input signal having information indicating that the front door 3 is opened is received, the front door 3 is being opened in a predetermined area of the main RAM 303. Process to store information. When the process of step S202-16 ends, the input port read process subroutine ends, and the process proceeds to step S203 of the interrupt process.

(Control command reception processing)
Next, the control command reception process performed by the process of step S210 of FIG. 60 will be described based on FIG. FIG. 62 is a diagram showing a subroutine of control command reception processing.

(Step S210-1)
In step S210-1, the main CPU 301 performs a process of determining whether or not an automatic medal insertion command has been received. Specifically, the main CPU 301 performs processing for determining whether or not an automatic medal insertion command has been received from the payout board 350. When it is determined that the automatic medal insertion command has been received (step S210-1 = Yes), the process proceeds to step S210-2, and when it is determined that the automatic medal insertion command has not been received. (Step S210-1 = No), the process proceeds to Step S210-3.

(Step S210-2)
In step S210-2, the main CPU 301 performs a medal automatic insertion command information storage process. Specifically, the main CPU 301 performs processing for storing information included in the automatic medal insertion command received from the payout board 350 in a predetermined area provided in the main RAM 303. More specifically, processing for updating the value of the insertion number counter provided in the main RAM 303 is performed. When the process of step S210-2 ends, the control command reception process subroutine ends, and the process proceeds to step S211 of the interrupt process.

(Step S210-3)
In step S210-3, the main CPU 301 performs processing for determining whether or not a settlement command has been received. Specifically, the main CPU 301 performs a process of determining whether or not a settlement start command or a settlement end command has been received from the payout board 350. If it is determined that a payment command has been received (step S210-3 = Yes), the process proceeds to step S210-4, and if it is determined that a payment command has not been received (step S210). -3 = No), the process proceeds to step S210-5.

(Step S210-4)
In step S210-4, the main CPU 301 performs a settlement command information storage process. Specifically, the main CPU 301 performs a process of storing the adjustment start command received from the payout board 350 or information included in the adjustment end command in a predetermined area provided in the main RAM 303. When the process of step S210-4 ends, the control command reception process subroutine ends, and the process proceeds to step S211 of the interrupt process.

(Step S210-5)
In step S210-5, the main CPU 301 performs processing for determining whether or not a medal insertion command has been received. Specifically, the main CPU 301 performs a process of determining whether or not a medal insertion command has been received from the payout board 350. If it is determined that a medal insertion command has been received (step S210-5 = Yes), the process proceeds to step S210-6, and if it is determined that a medal insertion command has not been received ( Step S210-5 = No) and the process proceeds to Step S210-7.

(Step S210-6)
In step S210-6, the main CPU 301 performs medal insertion command information storage processing. Specifically, the main CPU 301 performs processing for storing information included in the medal insertion command received from the payout board 350 in a predetermined area provided in the main RAM 303. More specifically, processing for updating the value of the insertion number counter provided in the main RAM 303 is performed. When the process of step S210-6 ends, the control command reception process subroutine ends, and the process proceeds to step S211 of the interrupt process.

(Step S210-7)
In step S210-7, the main CPU 301 performs processing for determining whether or not a BET command has been received. Specifically, the main CPU 301 performs processing for determining whether or not a BET command has been received from the payout board 350. If it is determined that a BET command has been received (step S210-7 = Yes), the process proceeds to step S210-8, and if it is determined that a BET command has not been received (step S210). −7 = No), the process proceeds to step S210-9.

(Step S210-8)
In step S210-8, the main CPU 301 performs BET command information storage processing. Specifically, the main CPU 301 performs processing for storing information included in the BET command received from the payout board 350 in a predetermined area provided in the main RAM 303. More specifically, processing for updating the value of the insertion number counter provided in the main RAM 303 is performed. When the process of step S210-8 is completed, the control command reception process subroutine is terminated, and the process proceeds to step S211 of the interrupt process.

(Step S210-9)
In step S210-9, the main CPU 301 performs processing for determining whether or not a display determination command has been received. Specifically, the main CPU 301 performs processing for determining whether or not a display determination command has been received from the payout board 350. When it is determined that the display determination command has been received (step S210-9 = Yes), the process proceeds to step S210-10, and when it is determined that the display determination command has not been received ( Step S210-9 = No), the process proceeds to step S210-11.

(Step S210-10)
In step S210-10, the main CPU 301 performs display determination command information storage processing. Specifically, the main CPU 301 performs processing for storing information included in the display determination command received from the payout board 350 in a predetermined area provided in the main RAM 303. When the process of step S210-10 ends, the control command reception process subroutine ends, and the process proceeds to step S211 of the interrupt process.

(Step S210-11)
In step S210-11, the main CPU 301 performs processing for determining whether or not a medal payout command has been received. Specifically, the main CPU 301 performs a process of determining whether or not a medal payout start command or a medal payout end command has been received from the payout board 350. If it is determined that a medal payout command has been received (step S210-11 = Yes), the process proceeds to step S210-12, and if it is determined that a medal payout command has not been received ( Step S210-11 = No), the process proceeds to step S210-13.

(Step S210-12)
In step S210-12, the main CPU 301 performs medal payout command information storage processing. Specifically, the main CPU 301 performs processing for storing information included in the medal payout start command or the medal payout end command received from the payout board 350 in a predetermined area provided in the main RAM 303. When the process of step S210-12 ends, the control command reception process subroutine ends, and the process proceeds to step S211 of the interrupt process.

(Step S210-13)
In step S210-13, the main CPU 301 performs processing for determining whether or not an illegal hit command has been received. Specifically, the main CPU 301 performs processing for determining whether an illegal hit command has been received from the payout board 350. If it is determined that the illegal hit command has been received (step S210-13 = Yes), the process proceeds to step S210-14, and if it is determined that the illegal hit command has not been received ( Step S210-13 = No), the process proceeds to step S210-15.

(Step S210-14)
In step S210-14, the main CPU 301 performs illegal hit command information storage processing. Specifically, the main CPU 301 performs processing for storing information included in the illegal hit command received from the payout board 350 in a predetermined area provided in the main RAM 303. The main CPU 301 performs processing for setting an illegal hit command in a main transmission data storage area provided in the main RAM 303. When the process of step S210-14 ends, the control command reception process subroutine ends, and the process proceeds to step S211 of the interrupt process.

(Step S210-15)
In step S210-15, the main CPU 301 determines whether or not a medal insertion error command has been received. Specifically, the main CPU 301 performs processing for determining whether or not a medal insertion error command has been received from the payout board 350. If it is determined that a medal insertion error command has been received (step S210-15 = Yes), the process proceeds to step S210-16, and if it is determined that a medal insertion error command has not been received. (Step S210-15 = No), the control command reception process subroutine is terminated, and the process proceeds to Step S211 of the interrupt process.

(Step S210-16)
In step S210-16, the main CPU 301 performs a medal insertion error command reception process. Specifically, the main CPU 301 performs processing for storing information included in the medal insertion error command received from the payout board 350 in a predetermined area provided in the main RAM 303. Further, in the interrupt process (see FIG. 60), the main CPU 301 performs control to display information indicating a medal insertion error on the payout number display 29. When the process of step S210-16 ends, the control command reception process subroutine ends, and the process proceeds to interrupt process step S211.

(Control command transmission processing)
Next, the control command transmission process performed by the process of step S211 of FIG. 60 will be described based on FIG. FIG. 63 is a diagram showing a subroutine of control command transmission processing.

(Step S211-1)
In step S211-1, the main CPU 301 performs a process of determining whether or not it is a door close command transmission time. Specifically, a process for determining whether or not a door close command is set in a main transmission data storage area provided in the main RAM 303 is performed. If it is determined that the door close command is being transmitted (step S211-1 = Yes), the process proceeds to step S211-2, and if it is determined that the door close command is not being transmitted ( Step S211-1 = No), the process proceeds to step S211-3.

(Step S211-2)
In step S211-2, the main CPU 301 performs door close command transmission processing. Specifically, the main CPU 301 performs processing for transmitting a door close command to the sub control board 400. When the process of step S211-2 ends, the control command transmission process subroutine ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-3)
In step S <b> 211-3, the main CPU 301 performs processing for determining whether or not it is a door open command transmission time. Specifically, a process for determining whether or not a door open command is set in the main transmission data storage area provided in the main RAM 303 is performed. When it is determined that the door open command is transmitted (step S211-3 = Yes), the process proceeds to step S211-4, and when it is determined that the door open command is not transmitted ( Step S211-3 = No), the process proceeds to step S211-5.

(Step S211-4)
In step S211-4, the main CPU 301 performs door open command transmission processing. Specifically, the main CPU 301 performs processing for transmitting a door open command to the sub control board 400. When the process of step S211-4 ends, the control command transmission process subroutine ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-5)
In step S <b> 211-5, the main CPU 301 performs processing to determine whether it is time to transmit a reel rotation start acceptance command. Specifically, the main CPU 301 performs a process of determining whether or not a reel rotation start acceptance command is set in the main transmission data storage area provided in the main RAM 303. If it is determined that the reel rotation start acceptance command is transmitted (step S211-5 = Yes), the process proceeds to step S211-6, and it is determined that the reel rotation start acceptance command is not transmitted. In that case (step S211-5 = No), the process proceeds to step S211-7.

(Step S211-6)
In step S211-6, the main CPU 301 performs a reel rotation start acceptance command transmission process. Specifically, the main CPU 301 performs a process of transmitting a reel rotation start acceptance command to the payout board 350 and the sub control board 400. When the process of step S211-6 ends, the control command transmission process subroutine ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-7)
In step S <b> 211-7, the main CPU 301 performs processing to determine whether or not it is time to send a conditional device command. Specifically, processing for determining whether or not a conditional device command is set in the main transmission data storage area provided in the main RAM 303 is performed. When it is determined that the conditional device command is transmitted (step S211-7 = Yes), the process proceeds to step S211-8, and when it is determined that the conditional device command is not transmitted ( Step S211-7 = No), the process proceeds to step S211-9.

(Step S211-8)
In step S211-8, the main CPU 301 performs a conditional device command transmission process. Specifically, the main CPU 301 performs processing for transmitting a conditional device command to the payout board 350 and the sub-control board 400. When the process of step S211-8 ends, the control command transmission process subroutine ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-9)
In step S211-9, the main CPU 301 determines whether or not it is time to transmit a reel rotation start command. Specifically, a process of determining whether or not a reel rotation start command is set in the main transmission data storage area provided in the main RAM 303 is performed. When it is determined that the reel rotation start command is being transmitted (step S211-9 = Yes), the process proceeds to step S211-10, and when it is determined that the reel rotation start command is not being transmitted. (Step S211-9 = No), the process proceeds to Step S211-11.

(Step S211-10)
In step S211-10, the main CPU 301 performs a reel rotation start command transmission process. Specifically, the main CPU 301 performs a process of transmitting a reel rotation start command to the sub control board 400. When the process of step S211-10 ends, the control command transmission process subroutine ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-11)
In step S <b> 211-11, the main CPU 301 performs processing for determining whether or not it is time to transmit a reel stop command. Specifically, a process for determining whether or not a reel stop command is set in a main transmission data storage area provided in the main RAM 303 is performed. If it is determined that the reel stop command is being transmitted (step S211-11 = Yes), the process proceeds to step S211-12, and if it is determined that the reel stop command is not being transmitted ( Step S211-11 = No), the process proceeds to step S211-13.

(Step S211-12)
In step S211-12, the main CPU 301 performs a reel stop command transmission process. Specifically, the main CPU 301 performs a process of transmitting a reel stop command to the payout board 350 and the sub control board 400. When the process of step S211-12 ends, the control command transmission process subroutine ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-13)
In step S211-13, the main CPU 301 performs a process of determining whether or not it is an illegal hit command transmission time. Specifically, processing for determining whether or not an illegal hit command is set in the main transmission data storage area provided in the main RAM 303 is performed. If it is determined that an illegal hit command is being transmitted (step S211-13 = Yes), the process proceeds to step S211-14, and if it is determined that an illegal hit command is not being transmitted ( Step S211-13 = No), the control command transmission process subroutine ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-14)
In step S211-14, the main CPU 301 performs illegal hit command transmission processing. Specifically, the main CPU 301 performs processing for transmitting an illegal hit command to the sub control board 400. Since the illegal hit error is an error in which the game cannot be continued, when the process of step S211-14 is completed, the process is terminated without shifting to the interrupt process of FIG.

(Main processing on payout board)
Next, the main process performed by the payout board 350 will be described with reference to FIG. The main process performed by the payout board 350 is a process performed based on the power switch 201sw being turned on.

(Step S301)
In step S301, the payout CPU 351 performs an initialization process. Specifically, the payout CPU 351 performs processing for clearing a predetermined area of the payout RAM 353 and the like. Then, when the process of step S301 ends, the process proceeds to step S302.

(Step S302)
In step S302, the payout CPU 351 performs a medal acceptance start process that will be described in detail later with reference to FIG. In this process, the payout CPU 351 performs a process of setting an automatic insertion initial timer when the re-game is operating. Then, when the process of step S302 ends, the process proceeds to step S303.

(Step S303)
In step S303, the payout CPU 351 performs a medal management process that will be described in detail later with reference to FIG. In this process, the payout CPU 351 performs a medal insertion check process, which will be described in detail later with reference to FIG. Then, when the process of step S303 ends, the process proceeds to step S304.

(Step S304)
In step S304, the payout CPU 351 performs processing for determining whether or not the value of the insertion number counter is “3”. Specifically, the payout CPU 351 performs a process of determining whether or not the value of the insertion number counter provided in the payout RAM 353 is “3”. If it is determined that the value of the inserted number counter is “3” (step S304 = Yes), the process proceeds to step S305, and it is determined that the value of the inserted number counter is not “3”. (Step S304 = No), the process proceeds to Step S302.

(Step S305)
In step S305, the payout CPU 351 performs processing for determining whether or not the left reel 18, the middle reel 19, and the right reel 20 are all stopped. Specifically, the payout CPU 351 performs a process of determining whether or not the left reel 18, the middle reel 19, and the right reel 20 are all stopped based on the reel stop command received from the main control board 300. If it is determined that the left reel 18, the middle reel 19, and the right reel 20 are all stopped (step S305 = Yes), the process proceeds to step S306, where the left reel 18, the middle reel 19, and the right reel 20 are transferred. If it is determined that all the reels have not stopped (step S305 = No), the process of step S305 is repeatedly executed until all of the left reel 18, the middle reel 19, and the right reel 20 are stopped.

(Step S306)
In step S306, the payout CPU 351 performs display determination processing which will be described in detail later with reference to FIG. In the process, the payout CPU 351 performs a process of calculating the payout number according to the combination of symbols displayed on the active line. Then, when the process of step S306 ends, the process proceeds to step S307.

(Step S307)
In step S307, the payout CPU 351 performs payout processing, which will be described in detail later with reference to FIG. In this process, the payout CPU 351 performs a process of paying out medals by driving the hopper 202 via the power supply board 200. Then, when the process of step S307 ends, the process proceeds to step S308.

(Step S308)
In step S308, the payout CPU 351 performs an initialization process at the end of the game. Specifically, the payout CPU 351 performs processing for clearing a predetermined area of the payout RAM 353. Then, when the process of step S308 ends, the process proceeds to step S302.

(Medal reception start processing)
Next, based on FIG. 65, the medal acceptance start process performed by the process of step S302 of FIG. 64 will be described. FIG. 64 is a diagram showing a subroutine for medal acceptance start processing.

(Step S302-1)
In step S302-1, the payout CPU 351 performs a process of determining whether or not the re-game operating flag is ON. Specifically, the payout CPU 351 displays whether or not the combination of symbols related to replay is displayed on the active line, and the regame operating flag in the regame operating flag storage area provided in the payout RAM 353 is ON. Determine whether. If it is determined that the re-game operating flag is ON (step S302-1 = Yes), the process proceeds to step S302-2, and it is determined that the re-game operating flag is not ON. In this case (step S302-1 = No), the medal acceptance start process subroutine is terminated, and the process proceeds to step S303 of the main process in the payout board.

(Step S302-2)
In step S302-2, the payout CPU 351 performs processing for setting an automatic insertion initial timer. Specifically, the payout CPU 351 performs a process of setting a predetermined value in a timer counter provided in the payout RAM 353 in order to provide a standby time for automatically inserting medals used in the previous game. Then, when the process of step S302-2 ends, the process proceeds to step S302-3.

(Step S302-3)
In step S302-3, the payout CPU 351 performs a timer wait process. Specifically, the payout CPU 351 performs a process of waiting until the value set in the timer counter becomes “0” by the process of step S302-2 or the process of step S302-8 described later. Then, when the process of step S302-3 ends, the process proceeds to step S302-4.

(Step S302-4)
In step S302-4, the payout CPU 351 performs processing for setting an automatic medal insertion command. Specifically, the payout CPU 351 stores the automatic medal insertion command stored in the payout RAM 353 in order to transmit the automatic medal insertion command to the main control board 300 and the sub control board 400. Perform processing to set the area. Here, the “medal automatic insertion command” is a command having information indicating that a medal used in the previous game is automatically inserted. Then, when the process of step S302-4 ends, the process proceeds to step S302-5.

(Step S302-5)
In step S302-5, the payout CPU 351 performs a process of adding “1” to the value of the insertion number counter. Specifically, the payout CPU 351 performs a process of adding “1” to the value of the inserted number counter provided in the payout RAM 353 with the number of medals used in the previous game as an upper limit. Then, when the process of step S302-5 ends, the process proceeds to step S302-6.

(Step S302-6)
In step S302-6, the payout CPU 351 performs a process of determining whether or not the value of the insertion number counter is “3”. Specifically, the payout CPU 351 adds “1” to the value of the insertion number counter provided in the payout RAM 353 by the process of step S302-6, and as a result, the value of the input number counter provided in the payout RAM 353 is obtained. It is determined whether or not “3” has been reached. When it is determined that the value of the inserted number counter is “3” (step S302-6 = Yes), the medal acceptance start processing subroutine is terminated, and the processing is performed at step S303 of the main processing on the payout board. Transition. On the other hand, if it is determined that the value of the inserted number counter is not “3” (step S302-6 = No), the process proceeds to step S302-7.

(Step S302-7)
In step S302-7, the payout CPU 351 performs processing for setting an automatic insertion interval timer. Specifically, the payout CPU 351 performs a process of setting a predetermined value in a timer counter provided in the payout RAM 353 in order to provide an interval for automatically inserting medals used in the previous game. Then, when the process of step S302-7 ends, the process proceeds to step S302-3.

(Medal management process)
Next, based on FIG. 66, the medal management process performed by the process of step S303 of FIG. 64 will be described. FIG. 66 shows a medal management process subroutine.

(Step S303-1)
In step S303-1, the payout CPU 351 performs a process of determining whether or not the re-game operating flag is ON. Specifically, the payout CPU 351 performs a process of determining whether or not the value of the re-game operating flag storage area provided in the payout RAM 353 is ON. If it is determined that the re-game in-operation flag is ON (step S303-1 = Yes), the medal management process subroutine is terminated, and the process proceeds to step S304 of the main process in the payout board. On the other hand, if it is determined that the re-game in-operation flag is not ON (step S303-1 = No), the process proceeds to step S303-2.

  In the present embodiment, when the re-game in-operation flag is ON, the medal management process subroutine is terminated and the medal insertion check process described later is not performed. Therefore, when the re-game in-operation flag is ON, the medal insertion is not accepted, but even when the re-game in-operation flag is ON, the medal insertion may be accepted. Good.

(Step S303-2)
In step S303-2, the payout CPU 351 performs a process of determining whether or not a medal has been inserted. Specifically, the payout CPU 351 performs processing for determining whether or not insertion of a medal is detected by the selector sensor 15s. If it is determined that a medal has been inserted (step S303-2 = Yes), the process proceeds to step S303-3, and if it is determined that no medal has been inserted (step S303-2). = No), the process proceeds to step S303-4.

(Step S303-3)
In step S303-3, the payout CPU 351 performs a medal insertion check process that will be described in detail later with reference to FIG. In this process, the payout CPU 351 determines the value of the input number counter provided in the payout RAM 353 based on the value of the input number counter provided in the payout RAM 353 or the value of the stored number counter provided in the payout RAM 353. Alternatively, a process of adding the value of the stored number counter provided in the payout RAM 353 is performed. When the process of step S303-3 ends, the medal management process subroutine ends, and the process proceeds to step S304 of the main process for the payout board.

(Step S303-4)
In step S303-4, the payout CPU 351 performs a process of setting “1” as the input request number. Specifically, the payout CPU 351 performs processing for setting “1” as the input request number in the register. Then, when the process of step S303-4 ends, the process proceeds to step S303-5.

(Step S303-5)
In step S303-5, the payout CPU 351 performs processing for determining whether or not the BET switch is ON. Specifically, the payout CPU 351 performs a process of determining whether or not an operation of the BET button 7 by the player is detected by the BET switch 7sw. More specifically, the BET switch input signal is received by the status board 100, and processing for determining whether information related to the BET switch input signal is stored in a predetermined area of the payout RAM 353 is performed. If it is determined that the BET switch is ON (step S303-5 = Yes), the process proceeds to step S303-8. If it is determined that the BET switch is not ON (step S303). −5 = No), the process proceeds to step S303-6.

(Step S303-6)
In step S303-6, the payout CPU 351 performs a process of setting “3” as the input request number. Specifically, the payout CPU 351 performs processing for updating the value of the requested number of sheets set in the register from “1” to “3”. Then, when the process of step S303-6 ends, the process proceeds to step S303-7.

(Step S303-7)
In step S303-7, the payout CPU 351 performs processing for determining whether or not the MAXBET switch is ON. Specifically, the payout CPU 351 performs processing for determining whether or not an operation of the MAXBET button 8 by the player is detected by the MAXBET switch 8sw. More specifically, a process of receiving a MAXBET switch input signal from the status board 100 and determining whether information related to the MAXBET switch input signal is stored in a predetermined area of the payout RAM 353 is performed. If it is determined that the MAXBET switch is ON (step S303-7 = Yes), the process proceeds to step S303-8, and if it is determined that the MAXBET switch is not ON (step S303). −7 = No), the process proceeds to step S303-11.

(Step S303-8)
In step S303-8, the payout CPU 351 performs a process of determining whether or not the value of the insertion number counter is “3”. Specifically, the payout CPU 351 performs processing to determine whether or not the value of the insertion number counter provided in the payout RAM 353 is “3”. If it is determined that the value of the inserted number counter is “3” (step S303-8 = Yes), the medal management process subroutine is terminated, and the process proceeds to step S304 of the main process on the payout board. To do. On the other hand, when it is determined that the value of the inserted number counter is not “3” (step S303-8 = No), the process proceeds to step S303-9.

(Step S303-9)
In step S303-9, the payout CPU 351 performs processing to determine whether or not the value of the stored number counter is “1” or more. Specifically, the payout CPU 351 performs a process of determining whether or not the value of the stored number counter provided in the payout RAM 353 is “1” or more. When it is determined that the value of the stored number counter is “1” or more (step S303-9 = Yes), the process proceeds to step S303-10, and the value of the stored number counter is “1” or more. If it is determined that it is not (step S303-9 = No), the medal management process subroutine is terminated, and the process proceeds to step S304 of the main process on the payout board.

(Step S303-10)
In step S303-10, the payout CPU 351 performs a stored medal insertion process, which will be described in detail later with reference to FIG. In this process, the payout CPU 351 performs a process of adding the value of the input number counter provided in the payout RAM 353 based on the value of the input number counter provided in the payout RAM 353. When the process of step S303-10 ends, the medal management process subroutine ends, and the process proceeds to step S304 of the main process in the payout board.

(Step S303-11)
In step S303-11, the payout CPU 351 performs a process of determining whether or not the settlement switch is ON. Specifically, the payout CPU 351 performs a process of determining whether or not an operation of the payment button 9 by the player is detected by the payment switch 9sw. More specifically, a payment switch input signal is received by the status board 100, and processing for determining whether or not information related to the payment switch input signal is stored in a predetermined area of the payout RAM 353 is performed. When it is determined that the settlement switch is ON (step S303-11 = Yes), the process proceeds to step S303-12, and when it is determined that the settlement switch is not ON (step S303). −11 = No), the medal management process subroutine is terminated, and the process proceeds to step S304 of the main process in the payout board.

(Step S303-12)
In step S303-12, the payout CPU 351 performs a process of determining whether the value of the insertion number counter or the value of the stored number counter is “1” or more. Specifically, the payout CPU 351 performs a process of determining whether the value of the input number counter provided in the payout RAM 353 or the value of the stored number counter is “1” or more. If it is determined that the value of the input number counter or the value of the stored number counter is “1” or more (step S303-12 = Yes), the process proceeds to step S303-13, and the input number counter When it is determined that the stored value counter value or the stored number counter value is not equal to or greater than “1” (step S303-12 = No), the medal management process subroutine is terminated, and the process proceeds to step S304 of the main process on the payout board. Migrate processing.

(Step S303-13)
In step S303-13, the payout CPU 351 performs processing for setting a settlement start command. Specifically, the payout CPU 351 transmits the payment start command to the payout transmission data storage area provided in the payout RAM 353 in order to transmit the payment start command to the main control board 300 and the sub control board 400. Perform the setting process. Here, the “settlement start command” is a command having information or the like indicating that a settlement process for returning medals stored in the gaming machine 1 to the player is started. Then, when the process of step S303-13 ends, the process proceeds to step S303-14.

(Step S303-14)
In step S303-14, the payout CPU 351 performs a process of determining whether or not the value of the insertion number counter is “1” or more. Specifically, the payout CPU 351 performs a process of determining whether or not the value of the insertion number counter provided in the payout RAM 353 is “1” or more. If it is determined that the value of the inserted number counter is “1” or more (step S303-14 = Yes), the process proceeds to step S303-15, and the value of the inserted number counter is “1” or more. If it is determined that this is not the case (step S303-14 = No), the process proceeds to step S303-18.

(Step S303-15)
In step S303-15, the payout CPU 351 performs inserted medal settlement processing. Specifically, the payout CPU 351 controls to return “1” medals by driving the hopper 202 via the power supply board 200 in order to return the bet medals to the player. Then, when the process of step S303-15 ends, the process proceeds to step S303-16.

(Step S303-16)
In step S303-16, the payout CPU 351 performs a process of subtracting “1” from the value of the inserted number counter. Specifically, the payout CPU 351 performs a process of subtracting “1” from the value of the insertion number counter provided in the payout RAM 353. Then, when the process of step S303-16 ends, the process proceeds to step S303-17.

(Step S303-17)
In step S303-17, the payout CPU 351 determines whether or not the value of the insertion number counter is “0”. Specifically, the payout CPU 351 subtracts “1” from the value of the insertion number counter provided in the payout RAM 353 by the processing of step S303-16, and as a result, the value of the input number counter provided in the payout RAM 353 is obtained. A process of determining whether or not “0” has been reached is performed. If it is determined that the value of the inserted number counter is “0” (step S303-17 = Yes), the process proceeds to step S303-19, and the value of the inserted number counter is not “0”. (Step S303-17 = No), the process proceeds to step S303-15, and the same process is performed until the value of the insertion number counter provided in the payout RAM 353 becomes “0”. Run repeatedly.

(Step S303-18)
In step S303-18, the payout CPU 351 performs a stored medal settlement process. Specifically, the payout CPU 351 controls to return “1” medals by driving the hopper 202 via the power supply board 200 in order to return the medals stored in the gaming machine 1 to the player. I do. Then, “1” is subtracted from the value of the stored number counter provided in the payout RAM 353, and as a result of performing the processing, it is determined whether or not the value of the stored number counter provided in the payout RAM 353 is “0”. The same processing is repeated until it is determined that the value of the stored number counter provided in the payout RAM 353 is “0”. Then, when the process of step S303-18 ends, the process proceeds to step S303-19.

(Step S303-19)
In step S303-19, the payout CPU 351 performs a process of setting a settlement end command. Specifically, the payout CPU 351 sends the payment end command to the payout transmission data storage area provided in the payout RAM 353 in order to transmit the payment end command to the main control board 300 and the sub control board 400. Perform the setting process. Here, the “payment end command” is information indicating that the bet medals have been returned to the player, or that the medals stored in the gaming machine 1 have been returned to the player. This command has information to that effect. When the process of step S303-19 ends, the medal management process subroutine ends, and the process proceeds to step S304 of the main process for the payout board.

(Medal insertion check process)
Next, based on FIG. 67, the medal insertion check process performed by the process of step S303-3 of FIG. 66 is demonstrated. FIG. 67 shows a subroutine for medal insertion check processing.

(Step S303-3-1)
In step S303-3-1, the payout CPU 351 performs medal passage monitoring start processing. Specifically, the payout CPU 351 performs processing for starting a medal passage monitoring process for determining whether or not a normal medal has been inserted by the selector 15. Then, when the process of step S303-3-1 ends, the process proceeds to step S303-3-2.

(Step S303-3-2)
In step S303-3-2, the payout CPU 351 performs processing to determine whether an error has been detected. Specifically, the payout CPU 351 performs processing for determining whether or not an error has been detected in the medal passage monitoring processing started by the medal passage monitoring start processing in step S303-3-1. If it is determined that an error has been detected (step S303-3-2 = Yes), the process proceeds to step S303-3-9. If it is determined that no error has been detected ( Step S303-3-2 = No), the process proceeds to step S303-3-3.

(Step S303-3-3)
In step S303-3-3, the payout CPU 351 performs a process of determining whether or not the medal passage monitoring process is finished. Specifically, the payout CPU 351 performs a process of determining whether or not the medal passage monitoring process started by the medal passage monitoring start process in step S303-3-1 has ended. If it is determined that the medal passage monitoring process has ended (step S303-3-3 = Yes), the process proceeds to step S303-3-4, and it is determined that the medal passage monitoring process has not ended. If it is determined (step S303-3-3 = No), the process proceeds to step S303-3-1 and the same process is executed until the medal passage monitoring process ends.

(Step S303-3-4)
In step S303-3-4, the payout CPU 351 performs processing for determining whether or not the medal insertion number is a MAX value. Specifically, the payout CPU 351 determines whether or not the value of the inserted number counter provided in the payout RAM 353 is “3” and the value of the stored number counter provided in the payout RAM 353 is “50”. Processing to determine is performed. If it is determined that the medal insertion number is the MAX value (step S303-3-4 = Yes), the medal insertion check processing subroutine is terminated, and the process proceeds to step S303-4 of the medal management processing. To do. On the other hand, when it is determined that the number of inserted medals is not the MAX value (step S303-3-4 = No), the process proceeds to step S303-3-5.

(Step S303-3-5)
In step S303-3-5, the payout CPU 351 performs a process of determining whether or not the value of the insertion number counter is “3”. Specifically, the payout CPU 351 performs processing to determine whether or not the value of the insertion number counter provided in the payout RAM 353 is “3”. If it is determined that the value of the inserted number counter is “3” (step S303-3-5 = Yes), the process proceeds to step S303-3-7. If it is determined that it is not “3” (step S303-3-5 = No), the process proceeds to step S303-3-6.

(Step S303-3-6)
In step S303-3-6, the payout CPU 351 performs a process of adding “1” to the value of the insertion number counter. Specifically, the payout CPU 351 performs a process of adding “1” to the value of the insertion number counter provided in the payout RAM 353. Then, when the process of step S303-3-6 ends, the process proceeds to step S303-3-8.

(Step S303-3-7)
In step S303-3-7, the payout CPU 351 performs a process of adding “1” to the value of the stored number counter. Specifically, the payout CPU 351 performs a process of adding “1” to the value of the stored number counter provided in the payout RAM 353. Then, when the process of step S303-3-7 ends, the process proceeds to step S303-3-8.

(Step S303-3-8)
In step S303-3-8, the payout CPU 351 performs processing for setting a medal insertion command. Specifically, the payout CPU 351 transmits the medal insertion command to the payout transmission data storage area provided in the payout RAM 353 in order to transmit the medal insertion command to the main control board 300 and the sub control board 400. Perform the setting process. Here, the “medal insertion command” is a command having information indicating that a normal medal has been inserted into the medal insertion slot 6. When the process of step S303-3-8 ends, the medal insertion check process subroutine ends, and the process proceeds to step S303-4 of the medal management process.

(Step S303-3-9)
In step S303-3-9, the payout CPU 351 performs processing for setting a medal insertion error command. Specifically, the payout CPU 351 stores the medal insertion error command stored in the payout RAM 353 in order to transmit the medal insertion error command to the main control board 300 and the sub control board 400. Perform processing to set the area. Here, the “medal insertion error command” is a command having information indicating that a medal inserted into the medal insertion slot 6 is not normally detected. When the process of step S303-3-9 ends, the medal insertion check process subroutine ends, and the process proceeds to step S303-4 of the medal management process.

(Storage medal insertion process)
Next, the stored medal insertion process performed by the process of step S303-10 of FIG. 66 will be described based on FIG. FIG. 68 is a diagram showing a subroutine of stored medal insertion processing.

(Step S303-10-1)
In step S <b> 303-10-1, the payout CPU 351 performs a process of determining whether or not the value of the stored number counter is equal to or greater than the requested number of sheets. Specifically, the payout CPU 351 performs a process of determining whether or not the value of the stored number counter provided in the payout RAM 353 is equal to or more than the input request number stored in the register. If it is determined that the value of the stored number counter is equal to or greater than the requested number of inputs (step S303-10-1 = Yes), the process proceeds to step S303-10-3, and the value of the stored number counter is If it is determined that the number is not equal to or greater than the requested number of insertions (step S303-10-1 = No), the process proceeds to step S303-10-2.

(Step S303-10-2)
In step S <b> 303-10-2, the payout CPU 351 performs processing for setting the value of the stored number counter to the input request number. Specifically, the payout CPU 351 performs a process of setting the value of the stored number counter provided in the payout RAM 353 to the value of the requested number of inputs stored in the register. Then, when the process of step S303-10-2 ends, the process proceeds to step S303-10-3.

(Step S303-10-3)
In step S303-10-3, the payout CPU 351 performs processing for setting a BET command. Specifically, the payout CPU 351 sets the BET command in the payout transmission data storage area provided in the payout RAM 353 in order to transmit the BET command to the main control board 300 and the sub control board 400. Process. Here, the “BET command” is a command having information indicating that a stored medal has been inserted by operating the BET button 7 and the MAXBET button 8. Then, when the process of step S303-10-3 ends, the process proceeds to step S303-10-4.

(Step S303-10-4)
In step S303-10-4, the payout CPU 351 performs a process of adding “1” to the value of the insertion number counter. Specifically, the payout CPU 351 performs a process of adding “1” to the value of the insertion number counter provided in the payout RAM 353. Then, when the process of step S303-10-4 ends, the process proceeds to step S303-10-5.

(Step S303-10-5)
In step S <b> 303-10-5, the payout CPU 351 performs a process of subtracting “1” from the input request number. Specifically, the payout CPU 351 performs a process of subtracting “1” from the value of the requested number of sheets stored in the register. Then, when the process of step S303-10-5 ends, the process proceeds to step S303-10-6.

(Step S303-10-6)
In step S303-10-6, the payout CPU 351 performs a process of subtracting “1” from the value of the stored number counter. Specifically, the payout CPU 351 performs a process of subtracting “1” from the value of the stored number counter provided in the payout RAM 353. Then, when the process of step S303-10-6 ends, the process proceeds to step S303-10-7.

(Step S303-10-7)
In step S <b> 303-10-7, the payout CPU 351 performs processing for determining whether or not the number of requested insertions is “0”. Specifically, the payout CPU 351 subtracts “1” from the value of the number of requested insertions stored in the register by the processing of step S303-10-5, and as a result, the value of the number of requested insertions stored in the register is obtained. A process of determining whether or not “0” has been reached is performed. If it is determined that the requested number of insertions is “0” (step S303-10-7 = Yes), the stored medal insertion process subroutine is terminated, and the process proceeds to step S304 of the main process on the payout board. Transition. On the other hand, if it is determined that the requested number of sheets is not “0” (step S303-10-7 = No), the process proceeds to step S303-10-3.

(Display judgment processing)
Next, based on FIG. 69, the display determination process performed by the process of step S306 of FIG. 64 will be described. FIG. 69 is a diagram showing a subroutine of display determination processing.

(Step S306-1)
In step S306-1, the payout CPU 351 performs an illegal hit error determination process. Specifically, the payout CPU 351 receives information on the winning combination included in the condition device command received from the main control board 300 and the left reel 18 included in the reel stop command received from the main control board 300. Based on the information related to the stop position, the information related to the stop position of the middle reel 19, and the information related to the stop position of the right reel 20, it is determined whether or not the combination of symbols displayed on the active line is normal. Do. Here, the payout CPU 351 performs a process of determining an illegal hit error when a combination of symbols related to the winning combination not determined by the internal lottery process in step S104 is displayed on the active line. Then, when the process of step S306-1 ends, the process proceeds to step S306-2.

(Step S306-2)
In step S <b> 306-2, the payout CPU 351 performs processing for determining whether or not an illegal hit error has occurred. Specifically, the payout CPU 351 performs a process of determining whether or not an illegal hit error has been determined by the illegal hit error determination process in step S306-1. If it is determined that there is an illegal hit error (step S306-2 = Yes), the process proceeds to step S306-3, and if it is determined that there is no illegal hit error (step S306-2). = No), the process proceeds to step S306-4.

(Step S306-3)
In step S306-3, the payout CPU 351 performs processing for setting an illegal hit command. Specifically, the payout CPU 351 performs a process of setting the illegal hit command in the payout transmission data storage area provided in the payout RAM 353 in order to transmit the illegal hit command to the main control board 300. . Here, the “illegal hit command” is a command having information indicating that a combination of symbols related to the winning combination not determined by the internal lottery process in step S104 is displayed on the active line. When the process in step S306-3 is completed, the process is terminated without returning to the main process in the payout board of FIG.

(Step S306-4)
In step S306-4, the payout CPU 351 performs processing for setting a display determination command. Specifically, the payout CPU 351 transmits the display determination command to the payout transmission data storage area provided in the payout RAM 353 in order to transmit the display determination command to the main control board 300 and the sub control board 400. Perform the setting process. Here, the “display determination command” is a command having information on a combination of symbols displayed on the active line. Then, when the process of step S306-4 ends, the process proceeds to step S306-5.

(Step S306-5)
In step S306-5, the payout CPU 351 performs a process of determining whether or not a winning is achieved. Specifically, the payout CPU 351 receives information related to the stop position of the left reel 18, information related to the stop position of the middle reel 19, and stop of the right reel 20 included in the reel stop command received from the main control board 300. Based on the information relating to the position and the symbol combination table (see FIGS. 6 to 8) provided in the payout ROM 352, a process for determining whether or not the symbol combination relating to winning is displayed on the active line is performed. . If it is determined that a winning is achieved (step S306-5 = Yes), the process proceeds to step S306-6, and if it is determined that no winning is achieved (step S306-5). = No), the process proceeds to step S306-7.

(Step S306-6)
In step S306-6, the payout CPU 351 performs a payout number calculation process. Specifically, the payout CPU 351 performs a process of calculating the payout number based on a combination of symbols related to winnings displayed on the active line. When the process of step S306-6 ends, the display determination process subroutine ends, and the process proceeds to step S307 of the main process for the payout board.

(Step S306-7)
In step S306-7, the payout CPU 351 performs processing for determining whether or not replay is established. Specifically, the payout CPU 351 performs a process of determining whether or not a symbol combination related to replay is displayed on the active line. If it is determined that replay has been established (step S306-7 = Yes), the process proceeds to step S306-8, and if it is determined that replay has not been established (step S306-7). = No), the display determination process subroutine is terminated, and the process proceeds to step S307 of the main process in the payout board.

(Step S306-8)
In step S306-8, the payout CPU 351 performs a process of turning on the re-game operating flag. Specifically, the payout CPU 351 performs a process of turning on the value of the regame operation flag in the regame operation flag storage area provided in the payout RAM 353. When the process of step S306-8 is completed, the display determination process subroutine is terminated, and the process proceeds to step S307 of the main process for the payout board.

(Payment processing)
Next, based on FIG. 70, the payout process performed by the process of step S307 in FIG. 64 will be described. FIG. 70 shows a payout processing subroutine.

(Step S307-1)
In step S307-1, the payout CPU 351 performs a process of determining whether or not the re-game operating flag is ON. Specifically, the payout CPU 351 performs a process of determining whether or not the regame operating flag is ON based on the value of the regame operating flag storage area provided in the payout RAM 353. If it is determined that the re-game operating flag is ON (step S307-1 = Yes), the process proceeds to step S307-3, and it is determined that the re-game operating flag is not ON. In the case (step S307-1 = No), the process proceeds to step S307-2.

(Step S307-2)
In step S307-2, the payout CPU 351 performs processing for setting a remaining payout number counter. Specifically, the payout CPU 351 performs processing for setting the payout number calculated in the payout number calculation processing in step S306-6 in a register. Then, when the process of step S307-2 ends, the process proceeds to step S307-3.

(Step S307-3)
In step S307-3, the payout CPU 351 performs a process of determining whether or not the value of the remaining payout number counter is “1” or more. Specifically, the payout CPU 351 performs a process of determining whether or not the value of the remaining payout number counter set in the register is “1” or more by the process of step S307-2. When it is determined that the value of the remaining payout number counter is “1” or more (step S307-3 = Yes), the process proceeds to step S307-4, and the value of the remaining payout number counter is “1”. If it is determined that it is not greater than or equal to “No” (step S307-3 = No), the payout process subroutine is terminated, and the process proceeds to step S308 of the main process on the payout board.

(Step S307-4)
In step S307-4, the payout CPU 351 performs processing for setting a medal payout start command. Specifically, the payout CPU 351 stores the medal payout start command stored in the payout RAM 353 in order to transmit the medal payout start command to the main control board 300 and the sub control board 400. Perform processing to set the area. Here, the “medal payout start command” is a command having information for starting the payout of medals. Then, when the process of step S307-4 ends, the process proceeds to step S307-5.

(Step S307-5)
In step S307-5, the payout CPU 351 performs a process of determining whether or not the value of the stored number counter is “50”. Specifically, the payout CPU 351 performs a process of determining whether or not the value of the stored number counter provided in the payout RAM 353 is “50”. When it is determined that the value of the stored number counter is “50” (step S307-5 = Yes), the process proceeds to step S307-7, and the value of the stored number counter is not “50”. Is determined (step S307-5 = No), the process proceeds to step S307-6.

(Step S307-6)
In step S307-6, the payout CPU 351 performs a process of adding “1” to the value of the stored number counter. Specifically, the payout CPU 351 performs a process of adding “1” to the value of the stored number counter provided in the payout RAM 353. Then, when the process of step S307-6 ends, the process proceeds to step S307-8.

(Step S307-7)
In step S307-7, the payout CPU 351 performs a medal payout process. Specifically, the payout CPU 351 controls to pay out “1” medals by driving the hopper 202 via the power supply board 200. Then, when the process of step S307-7 ends, the process proceeds to step S307-8.

(Step S307-8)
In step S307-8, the payout CPU 351 performs a process of adding “1” to the value of the acquired number counter. Specifically, the payout CPU 351 performs a process of adding “1” to the value of the acquired number counter provided in the payout RAM 353. Then, when the process of step S307-8 ends, the process proceeds to step S307-9.

(Step S307-9)
In step S307-9, the payout CPU 351 performs a process of subtracting “1” from the value of the remaining payout number counter. Specifically, the payout CPU 351 performs a process of subtracting “1” from the value of the remaining payout number counter set in the register. Then, when the process of step S307-9 ends, the process proceeds to step S307-10.

(Step S307-10)
In step S307-10, the payout CPU 351 performs a process of determining whether or not the value of the remaining payout number counter is “0”. Specifically, the payout CPU 351 determines whether or not the value of the remaining payout number counter is “0” as a result of subtracting “1” from the value of the remaining payout number counter in the process of step S307-9. Do. If it is determined that the value of the remaining payout number counter is “0” (step S307-10 = Yes), the process proceeds to step S307-11, and the value of the remaining payout number counter is “0”. If it is determined that this is not the case (step S307-10 = No), the process proceeds to step S307-5.

(Step S307-11)
In step S307-11, the payout CPU 351 performs processing for setting a medal payout end command. Specifically, the payout CPU 351 stores the medal payout end command stored in the payout RAM 353 in order to transmit the medal payout end command to the main control board 300 and the sub control board 400. Perform processing to set the area. Here, the “medal payout end command” is a command having information indicating that the payout of medals has ended. When the process of step S307-11 ends, the payout process subroutine ends, and the process proceeds to step S308 of the main process in the payout board.

(Interrupt processing on payout board)
Next, based on FIG. 71, the interruption process in the payout board will be described. Here, the interrupt process on the payout board is a process performed by interrupting every 1.49 ms with respect to the main process on the payout board.

(Step S401)
In step S401, the payout CPU 351 performs processing for saving the register. Specifically, the payout CPU 351 performs processing for saving the value of the register used at the time of step S401. Then, when the process of step S401 ends, the process proceeds to step S402.

(Step S402)
In step S402, the payout CPU 351 performs a payout board input port read process which will be described in detail later with reference to FIG. In the processing, the payout CPU 351 performs processing when a BET switch input signal, a MAXBET switch input signal, a settlement switch input signal, a selector sensor input signal, a hopper sensor input signal, a door opening / closing sensor input signal, and the like are input. Then, when the process of step S402 ends, the process proceeds to step S403.

(Step S403)
In step S403, the payout CPU 351 performs a payout board control command reception process which will be described in detail later with reference to FIG. In the process, the payout CPU 351 performs a process of storing information included in the command received from the main control board 300 in the payout RAM 353. Then, when the process of step S403 ends, the process proceeds to step S404.

(Step S404)
In step S404, the payout CPU 351 performs a payout board control command transmission process which will be described in detail later with reference to FIG. In this process, the payout CPU 351 performs a process of transmitting various commands to the main control board 300 and the sub control board 400. Then, when the process of step S404 ends, the process proceeds to step S405.

(Step S405)
In step S405, the payout CPU 351 performs a payout board port output process. Specifically, the payout CPU 351 performs a process of transmitting a predetermined signal to the status board 100, the power supply board 200, the main control board 300, and the sub control board 400. Then, when the process of step S405 ends, the process proceeds to step S406.

(Step S406)
In step S406, the payout CPU 351 performs a register restoration process. Specifically, the payout CPU 351 performs a process of restoring the saved register value in the process of step S401. Then, when the process of step S406 is completed, the interrupt process on the payout board is ended, and the process returns to the main process on the payout board.

(Payment board input port read processing)
Next, based on FIG. 72, the payout board input port reading process performed by the process of step S402 of FIG. 71 will be described. FIG. 72 is a diagram showing a subroutine of payout board input port reading processing.

(Step S402-1)
In step S402-1, the payout CPU 351 performs a process of determining whether or not a BET switch input signal has been received. Specifically, the payout CPU 351 performs processing for determining whether or not a BET switch input signal has been received from the status board 100. Here, the status board 100 performs processing for transmitting a BET switch input signal to the payout board 350 when the BET switch 7sw detects an operation of the BET button 7. When it is determined that the BET switch input signal has been received (step S402-1 = Yes), the process proceeds to step S402-2, and when it is determined that the BET switch input signal has not been received. (Step S402-1 = No), the process proceeds to Step S402-3.

(Step S402-2)
In step S402-2, the payout CPU 351 performs processing for determining that the BET switch has been turned ON. Specifically, the payout CPU 351 performs a process of setting information indicating that the BET switch 7sw is turned on in a predetermined area of the payout RAM 353. When the process of step S402-2 ends, the payout board input port reading process subroutine ends, and the process proceeds to step S403 of the interrupt process on the payout board.

(Step S402-3)
In step S402-3, the payout CPU 351 performs processing for determining whether or not a MAXBET switch input signal has been received. Specifically, the payout CPU 351 performs processing for determining whether or not a MAXBET switch input signal has been received from the status board 100. Here, the status board 100 performs processing for transmitting a MAXBET switch input signal to the payout board 350 when the MAXBET switch 8sw detects the operation of the MAXBET button 8. When it is determined that the MAXBET switch input signal has been received (step S402-3 = Yes), the process proceeds to step S402-4, and when it is determined that the MAXBET switch input signal has not been received. (Step S402-3 = No), the process proceeds to Step S402-5.

(Step S402-4)
In step S402-4, the payout CPU 351 performs processing for determining that the MAXBET switch has been turned ON. Specifically, the payout CPU 351 performs processing for setting information indicating that the MAXBET switch 8sw is turned ON in a predetermined area of the payout RAM 353. When the process of step S402-4 is completed, the payout board input port reading process subroutine is finished, and the process proceeds to step S403 of the interruption process in the payout board.

(Step S402-5)
In step S402-5, the payout CPU 351 performs a process of determining whether or not a settlement switch input signal has been received. Specifically, the payout CPU 351 performs processing for determining whether or not a payment switch input signal has been received from the status board 100. Here, the status board 100 performs a process of transmitting a settlement switch input signal to the payout board 350 when the settlement switch 9sw detects an operation of the settlement button 9. When it is determined that the settlement switch input signal has been received (step S402-5 = Yes), the process proceeds to step S402-6, and when it is determined that the settlement switch input signal has not been received. (Step S402-5 = No), the process proceeds to Step S402-7.

(Step S402-6)
In step S402-6, the payout CPU 351 performs processing for determining that the settlement switch has been turned ON. Specifically, the payout CPU 351 performs processing for setting information indicating that the settlement switch 9sw is turned on in a predetermined area of the payout RAM 353. When the processing in step S402-6 is completed, the payout board input port reading process subroutine is finished, and the process proceeds to step S403 of the interruption process in the payout board.

(Step S402-7)
In step S402-7, the payout CPU 351 performs a process of determining whether or not a selector sensor input signal has been received. Specifically, the payout CPU 351 performs processing for determining whether or not a selector sensor input signal has been received from the status board 100. Here, the status board 100 performs a process of transmitting a selector sensor input signal to the payout board 350 when the selector sensor 15s detects the passage of the medal. If it is determined that the selector sensor input signal has been received (step S402-7 = Yes), the process proceeds to step S402-8, and if it is determined that the selector sensor input signal has not been received. (Step S402-7 = No), the process proceeds to Step S402-9.

(Step S402-8)
In step S402-8, the payout CPU 351 performs processing for determining that the selector sensor is turned on. Specifically, the payout CPU 351 performs processing for setting information indicating that the selector sensor 15 s is turned on in a predetermined area of the payout RAM 353. When the processing of step S402-8 is completed, the payout board input port reading process subroutine is finished, and the process proceeds to step S403 of the interruption process in the payout board.

(Step S402-9)
In step S402-9, the payout CPU 351 performs a process of determining whether or not a hopper sensor input signal has been received. Specifically, the payout CPU 351 performs processing for determining whether or not a hopper sensor input signal has been received from the status board 100. Here, the status board 100 performs processing for transmitting a hopper sensor input signal to the payout board 350 when the passage of the medal to be paid out to the player by the hopper sensor 202s is detected. When it is determined that the hopper sensor input signal has been received (step S402-9 = Yes), the process proceeds to step S402-10, and when it is determined that the hopper sensor input signal has not been received. (Step S402-9 = No), the process proceeds to Step S402-11.

(Step S402-10)
In step S402-10, the payout CPU 351 performs processing for determining that the hopper sensor is turned on. Specifically, the payout CPU 351 performs processing for setting information indicating that the hopper sensor 202s is turned on in a predetermined area of the payout RAM 353. When the process of step S402-10 is completed, the payout board input port reading process subroutine is finished, and the process proceeds to step S403 of the interruption process in the payout board.

(Step S402-11)
In step S402-11, the payout CPU 351 performs a process of determining whether or not a door open / close sensor input signal has been received. Specifically, the payout CPU 351 performs processing for determining whether a door open / close sensor input signal has been received from the status board 100. Here, the status substrate 100 detects that the front door 3 is opened by the door opening / closing sensor 17s, or when the door opening / closing sensor 17s detects that the front door 3 is closed. The door opening / closing sensor input signal is transmitted. If it is determined that the door opening / closing sensor input signal has been received (step S402-11 = Yes), the process proceeds to step S402-12, and it is determined that the door opening / closing sensor input signal has not been received. In this case (step S402-11 = No), the payout board input port reading process subroutine is terminated, and the process proceeds to step S403 of the interruption process in the payout board.

(Step S402-12)
In step S402-12, the payout CPU 351 performs door-related processing. Specifically, the payout CPU 351 performs a process of rewriting a predetermined area of the payout RAM 353 in which information indicating that the door opening / closing sensor 17s is turned on is set, and sub-controls the door open command or the door close command. In order to transmit to the substrate 400, the door open command or the door close command is set in a payout transmission data storage area provided in the payout RAM 305. More specifically, a door open / close sensor input signal having information indicating that the front door 3 is closed when information indicating that the front door 3 is being opened is stored in a predetermined area of the payout RAM 353. Is received, a process for storing information indicating that the front door 3 is closed in a predetermined area of the payout RAM 353 is performed, and a door close command is stored in the payout transmission data storage area provided in the payout RAM 353. Perform processing to set. On the other hand, when information indicating that the front door 3 is closed is stored in a predetermined area of the payout RAM 353 and a door opening / closing sensor input signal having information indicating that the front door 3 is opened is received. Includes processing for storing information indicating that the front door 3 is being opened in a predetermined area of the payout RAM 353 and processing for setting a door open command in the payout transmission data storage area provided in the payout RAM 353. I do. When the process of step S402-12 is completed, the payout board input port reading process subroutine is finished, and the process proceeds to step S403 of the interruption process in the payout board.

(Receiving board control command reception processing)
Next, the payout board input port reading process performed by the process of step S402 of FIG. 71 will be described based on FIG. FIG. 73 is a diagram showing a subroutine of payout board control command reception processing.

(Step S403-1)
In step S403-1, the payout CPU 351 performs a process of determining whether or not a reel rotation start acceptance command has been received. Specifically, the payout CPU 351 performs a process of determining whether or not a reel rotation start acceptance command has been received from the main control board 300. If it is determined that the reel rotation start acceptance command has been received (step S403-1 = Yes), the process proceeds to step S403-2, and it is determined that the reel rotation start acceptance command has not been received. In the case (step S403-1 = No), the process proceeds to step S403-3.

(Step S403-2)
In step S403-2, the payout CPU 351 performs reel rotation start acceptance command information storage processing. Specifically, the payout CPU 351 performs processing to store information included in the reel rotation start acceptance command received from the main control board 300 in a predetermined area provided in the payout RAM 353. When the processing in step S403-2 is completed, the payout board control command reception processing subroutine is finished, and the process proceeds to step S404 of the interruption process in the payout board.

(Step S403-3)
In step S403-3, the payout CPU 351 performs processing for determining whether or not a conditional device command has been received. Specifically, the payout CPU 351 performs processing for determining whether or not a conditional device command has been received from the main control board 300. If it is determined that a conditional device command has been received (step S403-3 = Yes), the process proceeds to step S403-4, and if it is determined that a conditional device command has not been received ( Step S403-3 = No), the process proceeds to step S403-5.

(Step S403-4)
In step S403-4, the payout CPU 351 performs a condition device command information storage process. Specifically, the payout CPU 351 performs processing for storing information included in the condition device command received from the main control board 300 in a predetermined area provided in the payout RAM 353. When the process of step S403-4 ends, the payout board control command reception process subroutine ends, and the process proceeds to step S404 of the interruption process in the payout board.

(Step S403-5)
In step S403-5, the payout CPU 351 performs a process of determining whether or not a reel stop command has been received. Specifically, the payout CPU 351 performs processing for determining whether or not a reel stop command has been received from the main control board 300. If it is determined that the reel stop command has been received (step S403-5 = Yes), the process proceeds to step S403-6. If it is determined that the reel stop command has not been received (step S403-5 = Yes) In step S403-5 = No), the payout board control command reception process subroutine is terminated, and the process proceeds to step S404 of the interruption process in the payout board.

(Step S403-6)
In step S403-6, the payout CPU 351 performs reel stop command information storage processing. Specifically, the payout CPU 351 performs processing for storing information included in the reel stop command received from the main control board 300 in a predetermined area provided in the payout RAM 353. When the process of step S403-6 is completed, the payout board control command reception process subroutine is finished, and the process proceeds to step S404 of the interruption process in the payout board.

(Delivery board control command transmission process)
Next, based on FIG. 74, the payout board input port reading process performed by the process of step S404 of FIG. 71 will be described. FIG. 74 is a diagram showing a subroutine of payout board control command transmission processing.

(Step S404-1)
In step S404-1, the payout CPU 351 performs a process of determining whether or not it is time to send an automatic medal insertion command. Specifically, the payout CPU 351 performs a process of determining whether or not an automatic medal insertion command is set in a payout transmission data storage area provided in the payout RAM 353. If it is determined that the medal automatic insertion command is transmitted (step S404-1 = Yes), the process proceeds to step S404-2, and if it is determined that the medal automatic insertion command is not transmitted. (Step S404-1 = No), the process proceeds to Step S404-3.

(Step S404-2)
In step S404-2, the payout CPU 351 performs a medal automatic insertion command transmission process. Specifically, the payout CPU 351 performs processing for transmitting an automatic medal insertion command to the main control board 300 and the sub control board 400. When the process of step S404-2 is completed, the subroutine of the payout board control command transmission process is ended, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-3)
In step S404-3, the payout CPU 351 performs a process of determining whether or not it is time to send a payment command. Specifically, the payout CPU 351 performs processing for determining whether or not a payment start command or a payment end command is set in the payout transmission data storage area provided in the payout RAM 353. If it is determined that the payment command is being transmitted (step S404-3 = Yes), the process proceeds to step S404-4. If it is determined that the payment command is not being transmitted (step S404). -3 = No), the process proceeds to step S404-5.

(Step S404-4)
In step S404-4, the payout CPU 351 performs a settlement command transmission process. Specifically, the payout CPU 351 performs processing for transmitting a settlement command to the main control board 300 and the sub control board 400. More specifically, the payout CPU 351 starts the checkout for the main control board 300 and the sub control board 400 when the checkout start command is set in the payout transmission data storage area provided in the payout RAM 353. If the payment completion command is set in the payout transmission data storage area provided in the payout RAM 353, the payment completion command is sent to the main control board 300 and the sub control board 400. Process to send. When the process of step S404-4 is completed, the subroutine of the payout board control command transmission process is ended, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-5)
In step S404-5, the payout CPU 351 performs a process of determining whether or not it is a medal insertion command transmission time. Specifically, the payout CPU 351 performs processing for determining whether or not a medal insertion command is set in the payout transmission data storage area provided in the payout RAM 353. If it is determined that the medal insertion command is transmitted (step S404-5 = Yes), the process proceeds to step S404-6. If it is determined that the medal insertion command is not transmitted, ( Step S404-5 = No), the process proceeds to step S404-7.

(Step S404-6)
In step S404-6, the payout CPU 351 performs medal insertion command transmission processing. Specifically, the payout CPU 351 performs processing for transmitting a medal insertion command to the main control board 300 and the sub control board 400. When the process of step S404-6 is completed, the payout board control command transmission process subroutine is finished, and the process proceeds to step S405 of the interruption process in the payout board.

(Step S404-7)
In step S404-7, the payout CPU 351 performs processing to determine whether it is time to send a BET command. Specifically, the payout CPU 351 performs processing for determining whether or not a BET command is set in the payout transmission data storage area provided in the payout RAM 353. If it is determined that the BET command is being transmitted (step S404-7 = Yes), the process proceeds to step S404-8. If it is determined that the BET command is not being transmitted (step S404). −7 = No), the process proceeds to step S404-9.

(Step S404-8)
In step S404-8, the payout CPU 351 performs BET command transmission processing. Specifically, the payout CPU 351 performs processing for transmitting a BET command to the main control board 300 and the sub control board 400. When the processing of step S404-8 is completed, the payout board control command transmission process subroutine is finished, and the process proceeds to step S405 of the interruption process in the payout board.

(Step S404-9)
In step S404-9, the payout CPU 351 performs processing for determining whether or not it is time to transmit a display determination command. Specifically, the payout CPU 351 performs processing to determine whether or not a display determination command is set in the payout transmission data storage area provided in the payout RAM 353. If it is determined that the display determination command is being transmitted (step S404-9 = Yes), the process proceeds to step S404-10, and if it is determined that the display determination command is not being transmitted ( In step S404-9 = No), the process proceeds to step S404-11.

(Step S404-10)
In step S404-10, the payout CPU 351 performs display determination command transmission processing. Specifically, the payout CPU 351 performs processing for transmitting a display determination command to the main control board 300 and the sub control board 400. When the process of step S404-10 is completed, the subroutine of the payout board control command transmission process is ended, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-11)
In step S404-11, the payout CPU 351 performs a process of determining whether or not it is a medal payout command transmission time. Specifically, the payout CPU 351 performs processing for determining whether or not a medal payout start command or a medal payout end command is set in the payout transmission data storage area provided in the payout RAM 353. If it is determined that the medal payout command is transmitted (step S404-11 = Yes), the process proceeds to step S404-12, and if it is determined that the medal payout command is not transmitted ( Step S404-11 = No), the process proceeds to step S404-13.

(Step S404-12)
In step S404-12, the payout CPU 351 performs a medal payout command transmission process. Specifically, the payout CPU 351 performs processing for transmitting a medal payout command to the main control board 300 and the sub control board 400. More specifically, when the medal payout start command is set in the payout transmission data storage area provided in the payout RAM 353, the payout CPU 351 issues a medal to the main control board 300 and the sub control board 400. When a process for transmitting a payout start command is performed and a medal payout end command is set in the payout transmission data storage area provided in the payout RAM 353, a medal is issued to the main control board 300 and the sub control board 400 A process for transmitting a payout end command is performed. When the process of step S404-12 ends, the payout board control command transmission process subroutine ends, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-13)
In step S404-13, the payout CPU 351 performs a process of determining whether or not it is a door command transmission time. Specifically, the payout CPU 351 performs processing for determining whether a door open command or a door close command is set in a payout transmission data storage area provided in the payout RAM 353. If it is determined that the door command is being transmitted (step S404-13 = Yes), the process proceeds to step S404-14. If it is determined that the door command is not being transmitted (step S404). −13 = No), the process proceeds to step S404-15.

(Step S404-14)
In step S404-14, the payout CPU 351 performs door command transmission processing. Specifically, the payout CPU 351 performs processing for transmitting a door command to the sub control board 400. More specifically, when the door open command is set in the payout transmission data storage area provided in the payout RAM 353, the payout CPU 351 transmits the door open command to the sub control board 400. When the door close command is set in the payout transmission data storage area provided in the payout RAM 353, the door close command is transmitted to the sub control board 400. When the process of step S404-14 is completed, the subroutine of the payout board control command transmission process is ended, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-15)
In step S404-15, the payout CPU 351 performs a process of determining whether or not it is an error command transmission time. Specifically, the payout CPU 351 determines whether or not a command related to various errors such as a medal insertion error command and an illegal hit command is set in the payout transmission data storage area provided in the payout RAM 353. I do. If it is determined that the error command is being transmitted (step S404-15 = Yes), the process proceeds to step S404-16, and if it is determined that the error command is not being transmitted (step S404). −15 = No), the payout board control command transmission process subroutine is terminated, and the process proceeds to step S405 of the interruption process in the payout board.

(Step S404-16)
In step S404-16, the payout CPU 351 performs an error command transmission process. Specifically, the payout CPU 351 performs processing for transmitting an error command to the sub control board 400. More specifically, when the illegal hit command is set in the payout transmission data storage area provided in the payout RAM 353, the payout CPU 351 transmits the illegal hit command to the main control board 300. If the medal insertion error command is set in the payout transmission data storage area provided in the payout RAM 353, processing for transmitting the medal insertion error command to the sub control board 400 is performed. When the processing in step S404-16 is completed, the payout board control command transmission process subroutine is finished, and the process proceeds to step S405 of the interruption process in the payout board.

(Main processing on sub-control board)
Next, the main process in the sub control board will be described with reference to FIG.

(Step S501)
In step S501, the sub CPU 401 performs an initialization process. Specifically, the sub CPU 401 performs processing such as error checking of the sub RAM 403. Then, when the process of step S501 ends, the process proceeds to step S502.

(Step S502)
In step S502, the sub CPU 401 performs inter-substrate communication processing, which will be described in detail later with reference to FIG. In this process, the sub CPU 401 performs a process of analyzing a command transmitted from the main control board 300, a command transmitted from the payout board 350, and the like. Then, when the process of step S502 ends, the process proceeds to step S503.

(Step S503)
In step S503, the sub CPU 401 performs sound control processing. Specifically, the sub CPU 401 performs the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker via the amplifier board 500 based on the content of the effect determined by the sub effect determination process described later. The process of outputting sound from 42 is performed. Then, when the process of step S503 ends, the process proceeds to step S504.

(Step S504)
In step S504, the sub CPU 401 performs lamp control processing. Specifically, the sub CPU 401 performs the Bonus display unit 32, the ART display unit 33, and the stop button operation display unit 34 via the panel LED relay board 700 based on the content of the effect determined by the sub effect determination process described later. The start lever LED 35, the MAXBET button LED 721, the stop button LED 722, the effect button LED 723, and the waist panel LED 724 are controlled. In addition, the sub CPU 401 performs top LED 661, corner LED 662, side LED 663, and saucer side LED 664 via the effect control board 600 and the effect device drive relay board 550 based on the effect content determined by the sub effect determining process described later. The tray LED 665 is controlled. Then, when the process of step S504 ends, the process proceeds to step S505.

(Step S505)
In step S505, the sub CPU 401 performs image control processing. Specifically, the sub CPU 401 controls the liquid crystal display device 45 via the effect control board 600 based on the effect contents determined by the sub effect determining process described later. Then, when the process of step S505 ends, the process proceeds to step S506.

(Step S506)
In step S506, the sub CPU 401 performs various switch detection processing. Specifically, the sub CPU 401 performs a process of executing a predetermined process when the effect button detection sensor 709sw detects an operation of the effect button 21 or when the cross key board 710 detects an operation of the cross key 22. . Then, when the process of step S506 ends, the process proceeds to step S502.

(Inter-board communication processing)
Next, based on FIG. 76, the inter-substrate communication process performed by the process of step S502 of FIG. 75 will be described. FIG. 76 shows a subroutine for inter-substrate communication processing.

(Step S502-1)
In step S502-1, the sub CPU 401 performs processing for determining whether or not a different command has been received. Specifically, the sub CPU 401 performs a process of determining whether a command received from the main control board 300 or the payout board 350 is a command different from the command received last time. If it is determined that a different command has been received (step S502-1 = Yes), the process proceeds to step S502-2, and if it is determined that a different command has not been received (step S502). −1 = No), the main board communication process subroutine is terminated, and the process proceeds to step S503 of the main process in the sub control board.

(Step S502-2)
In step S502-2, the sub CPU 401 performs a game information storage process. Specifically, the sub CPU 401 performs processing for creating game information based on a command different from the previously transmitted command and storing it in a predetermined storage area of the sub RAM 403. Then, when the process of step S502-2 ends, the process proceeds to step S502-3.

(Step S502-3)
In step S502-3, the sub CPU 401 performs a command analysis process that will be described in detail later with reference to FIG. In this process, the sub CPU 401 executes a process based on the game information stored by the process of step S502-2. Then, when the process of step S502-3 is completed, the main board communication process subroutine is ended, and the process proceeds to step S503 of the main process in the sub control board.

(Command analysis processing)
Next, based on FIG. 77, the command analysis process performed by the process of step S502-3 of FIG. 76 will be described. FIG. 75 is a diagram showing a subroutine of command analysis processing.

(Step S502-3-1)
In step S502-3-1, the sub CPU 401 performs processing for each command, which will be described in detail later with reference to FIG. In the processing, the sub CPU 401 performs processing according to the command received from the main control board 300. Then, when the process of step S502-3-1 ends, the process proceeds to step S502-3-2.

(Step S502-3-2)
In step S502-3-2, the sub CPU 401 performs lamp data determination processing. Specifically, sub CPU401 performs the process which determines the lamp data corresponding to the production content determined by the process according to command of step S502-3-1. Then, when the process of step S502-3-2 ends, the process proceeds to step S502-3-3.

(Step S502-3-3)
In step S502-3-3, the sub CPU 401 performs sound data determination processing. Specifically, the sub CPU 401 performs processing for determining sound data corresponding to the effect content determined by the command-specific processing in step S502-3-1. Then, when the process of step S502-3-3 ends, the process proceeds to step S502-3-4.

(Step S502-3-4)
In step S502-3-4, the sub CPU 401 performs image data determination processing. Specifically, the sub CPU 401 performs a process of determining image data corresponding to the effect content determined by the command-specific process in step S502-3-1. When the process of step S502-3-4 ends, the command analysis process subroutine ends, and the process proceeds to step S503 of the main process in the sub control board.

(Processing by command)
Next, based on FIG. 78, the command-by-command processing performed by the processing in step S502-3-1 in FIG. 77 will be described. FIG. 78 is a diagram showing a subroutine for processing by command.

(Step S502-3-1-1)
In step S502-3-1-1, the sub CPU 401 performs processing according to the received command. Specifically, the sub CPU 401 performs processing according to commands received from the main control board 300 and the payout board 350. Then, when the process of step S502-3-1-1 ends, the process proceeds to step S502-3-1-2.

(Step S502-3-1-2)
In step S502-3-1-2, the sub CPU 401 performs a sub effect determination process. Specifically, the sub CPU 401 performs processing for determining an effect executed by the liquid crystal display device 45 or the like based on the received command and the effect determination table (see FIG. 26). When the process of step S502-3-1-2 ends, the subroutine for each command process ends, and the process proceeds to step S502-3-2 of the command analysis process.

  Here, if the sub CPU 401 receives a door open command from the main control board 300 or the payout board 350 in the sub effect determination process in step S502-3-1-2, the upper left speaker 39, the lower left speaker An image indicating that the front door 3 is open and the liquid crystal display device 45 is opened by the sound of the front speaker 40, the upper right speaker 41, and the lower right speaker 42. The process which determines the effect which displays is performed.

  In addition, when the sub CPU 401 receives a door close command from the main control board 300 or the payout board 350 in the sub effect determination process of step S502-3-1-2, the left upper speaker 39, the lower left speaker The notification that the front door 3 was opened, which was performed by the speaker 40, the upper right speaker 41, and the lower right speaker 42, was terminated and displayed on the liquid crystal display device 45 before the front door 3 was opened. Processing for determining an effect for displaying an image is performed.

  Further, when the sub CPU 401 receives a reel rotation start acceptance command from the main control board 300 in the sub effect determination process in step S502-3-1-2, the sub CPU 401 determines the effect when the start lever 10 is operated. Perform the process.

  Further, in the sub effect determination process of step S502-3-1-2, the sub CPU 401 performs a process of determining an effect corresponding to the winning combination when the conditional device command is received from the main control board 300. .

  Further, when the sub CPU 401 receives a reel rotation start command from the main control board 300 in the sub effect determination process of step S502-3-1-2, the sub CPU 401 performs a process of determining an effect at the start of reel rotation. Do.

  In addition, when the sub CPU 401 receives a reel stop command from the main control board 300 in the sub effect determination process in step S502-3-1-2, the sub CPU 401 performs a process of determining an effect at the time of reel stop.

  In addition, when the sub CPU 401 receives an illegal hit command from the main control board 300 in the sub effect determining process in step S502-3-1-2, the sub CPU 401 determines an effect that informs that an illegal hit error has occurred. Perform the process.

  In addition, when the sub CPU 401 receives an automatic medal insertion command from the payout board 350 in the sub effect determination process of step S502-3-1-2, the sub CPU 401 performs a process of determining an effect at the time of automatic medal insertion. .

  Further, when the sub CPU 401 receives a payment start command from the payout board 350 in the sub effect determination process of step S502-3-1-2, the sub CPU 401 performs a process of determining the effect at the start of payment.

  In addition, when the sub CPU 401 receives a payment end command from the payout board 350 in the sub effect determination process of step S502-3-1-2, An effect of stopping the sound at the time of settlement output by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42 and outputting the sound that was output before receiving the settlement start command. Perform the decision process.

  Further, when the sub CPU 401 receives a medal insertion command from the payout board 350 in the sub effect determination process in step S502-3-1-2, the sub CPU 401 determines an effect for outputting a sound at the time of medal insertion. I do.

  Further, when the sub CPU 401 receives a medal insertion error command from the payout board 350 in the sub effect determination process of step S502-3-1-2, the sub CPU 401 performs a process of determining an effect to output an error sound. .

  Further, when the sub CPU 401 receives a BET command from the payout board 350 in the sub effect determining process in step S502-3-1-2, the sub CPU 401 outputs a sound when the BET button 7 and the MAX BET button 8 are operated. The process which determines the production to perform is performed.

  Further, when the sub CPU 401 receives a display determination command from the payout board 350 in the sub effect determination process in step S502-3-1-2, all of the left reel 18, the middle reel 19, and the right reel 20 are included. The process which determines the production when stops is performed.

  Further, when the sub CPU 401 receives a medal payout start command from the payout board 350 in the sub effect determining process of step S502-3-1-2, the sub CPU 401 performs a process of determining an effect at the time of medal payout.

  Further, when the sub CPU 401 receives a medal payout end command from the payout board 350 in the sub effect determining process of step S502-3-1-2, the sub CPU 401 performs a process of determining an effect at the end of the medal payout. .

(List of commands transmitted by the main control board)
Next, a list of commands transmitted by the main control board will be described with reference to FIG.

  The main control board 300 performs a process of transmitting various commands to the payout board 350 and the sub control board 400. Depending on the type of command, the main control board 300 sends a command to the sub control board 400 and Commands to be transmitted to the board 350 and the sub-control board 400 are defined.

  As shown in FIG. 79, in the present embodiment, examples of commands that the main control board 300 transmits only to the sub control board 400 include a door close command, a door open command, and a reel rotation start command.

  Here, when receiving the door open command from the main control board 300, the sub control board 400 performs control to notify that the front door 3 is open. Specifically, the sub-control board 400 informs that the front door 3 is opened by voice or the like by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42, and Control is performed to display an image indicating that the front door 3 is open on the liquid crystal display device 45.

  Further, the sub control board 400 performs control to notify that the front door 3 is closed when a door close command is received from the main control board 300. Specifically, the sub-control board 400 ends the notification that the front door 3 is open, which was performed by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. Then, control is performed so that an image indicating that the front door 3 displayed on the liquid crystal display device 45 is open is not displayed.

  In addition, when the sub-control board 400 receives a reel rotation start command from the main control board 300, the sub-control board 400 performs a process of executing an effect at the start of reel rotation. Specifically, the sub-control board 400 controls the output of the effect sound by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42 and displays the effect image on the liquid crystal display device 45. Take control.

  On the other hand, as shown in FIG. 79, in this embodiment, as an example of commands that the main control board 300 transmits to the payout board 350 and the sub-control board 400, a reel rotation start acceptance command, a condition device command, a reel An example is a stop command.

  Here, the payout board 350 performs processing for storing information related to the reel rotation start acceptance command based on the reception of the reel rotation start acceptance command from the main control board 300. The stored information is used for error determination. For example, when the payout CPU 351 receives a reel stop command even though the information related to the reel rotation start acceptance command is not stored in a predetermined area of the payout RAM 353, the payout CPU 351 receives the command received from the main control board 300. It is determined that the order is not normal, and an error process is performed. On the other hand, when the sub-control board 400 receives a reel rotation start acceptance command from the main control board 300, the sub-control board 400 performs a process of performing an effect when the start lever 10 is operated. Specifically, the sub-control board 400 controls the output of the effect sound by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42 and displays the effect image on the liquid crystal display device 45. Take control.

  The payout board 350 performs processing for storing information related to the condition device command based on the reception of the condition device command from the main control board 300. The stored information is used for error determination. For example, the payout CPU 351 is an illegal hit error based on the combination of the information related to the winning combination included in the conditional device command stored in a predetermined area of the payout RAM 353 and the symbol displayed on the active line. The process which determines whether or not is performed. On the other hand, when the sub-control board 400 receives the condition device command from the main control board 300, the sub-control board 400 performs a process of executing an effect corresponding to the winning combination. Specifically, the sub-control board 400 controls the output of the effect sound by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42, and displays the effect image on the liquid crystal display device 45. Control the display.

  Further, the payout board 350 performs processing for storing information related to the reel stop command based on the reception of the reel stop command from the main control board 300. The stored information is used for display determination processing. Specifically, the payout CPU 351 includes information on the stop position of the left reel 18 included in the reel stop command stored in a predetermined area of the payout RAM 353, information on the stop position of the middle reel 19, and right A display determination process is performed based on information related to the stop position of the reel 20. On the other hand, when the sub control board 400 receives a reel stop command from the main control board 300, the sub control board 400 performs a process of executing an effect at the time of reel stop. Specifically, the sub-control board 400 controls the output of the effect sound by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42 and displays the effect image on the liquid crystal display device 45. Take control.

  Although not shown, an example of a command transmitted from the main control board 300 only to the payout board 350 is a command error. Here, the command error is an error that occurs during communication between the main control board 300 and the payout board 350. When the payout board 350 receives information indicating a command error from the main control board 300, the payout board 350 performs processing at the time of the command error and also notifies the sub control board 400 that the command error has occurred. Send. When the sub-control board 400 receives information indicating a command error from the payout board 350, the sub-control board 400 performs control to notify that the command error has occurred.

  As described above, in the present embodiment, the main control board 300 transmits one command only to the payout board 350, transmits only one command to the sub control board 400, and sends to the payout board 350 and the sub control board 400. May be sent. Then, the payout board 350 and the sub-control board 400 perform processing according to the received command.

(List of commands sent by payout board)
Next, a list of commands transmitted by the payout board will be described with reference to FIG.

  The payout board 350 performs a process of transmitting various commands to the main control board 300 and the sub control board 400. Depending on the type of command, A command to be transmitted only to the control board 400 and a command to be transmitted to the main control board 300 and the sub control board 400 are defined.

  As shown in FIG. 80, in this embodiment, an illegal hit command is an example of a command that the payout board 350 transmits only to the main control board 300.

  Here, the main control board 300 stores the illegal hit error information on the basis of the reception of the illegal hit command from the payout board 350 (step S210-14), and then the illegal hit to the sub control board 400. Processing for transmitting a command is performed (step S211-14).

  Further, as shown in FIG. 80, in this embodiment, examples of commands that the payout board 350 transmits only to the sub-control board 400 include a door close command and a door open command.

  Here, when the sub control board 400 receives a door open command from the payout board 350, the sub control board 400 performs control to notify that the front door 3 is open. Specifically, the sub-control board 400 informs that the front door 3 is opened by voice or the like by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42, and Control is performed to display an image indicating that the front door 3 is open on the liquid crystal display device 45.

  In addition, when the sub control board 400 receives a door close command from the payout board 350, the sub control board 400 performs control to notify that the front door 3 is closed. Specifically, the sub-control board 400 ends the notification that the front door 3 is open, which was performed by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. Then, control is performed so that an image indicating that the front door 3 displayed on the liquid crystal display device 45 is open is not displayed.

  Further, as shown in FIG. 80, in this embodiment, as an example of commands that the payout board 350 transmits to the main control board 300 and the sub control board 400, an automatic medal insertion command, a settlement start command, a settlement end command, a medal An insertion command, a medal insertion error command, a BET command, a display determination command, a medal payout start command, and a medal payout end command.

  Here, the main control board 300 controls the first BET lamp 25, the second BET lamp 26, and the third BET lamp 27 based on the reception of the automatic medal insertion command from the payout board 350. On the other hand, when the sub-control board 400 receives an automatic medal insertion command from the payout board 350, the sub-control board 400 performs a process of executing an effect upon automatic medal insertion. Specifically, the sub-control board 400 performs control to output a sound at the time of automatic medal insertion by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42.

  In addition, the main control board 300 performs control for subtracting and displaying the stored number indicator 28 based on the receipt of the settlement start command from the payout board 350. On the other hand, when the sub-control board 400 receives a payment start command from the payout board 350, the sub-control board 400 performs a process of executing an effect at the start of payment. Specifically, the sub-control board 400 performs control to output a sound at the time of settlement by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42.

  Further, the main control board 300 performs control to stop the subtraction display of the stored number indicator 28 at “0” based on the receipt of the settlement end command from the payout board 350. On the other hand, when the sub-control board 400 receives the payment end command from the payout board 350, the sub-control board 400 outputs the sound at the time of payment output from the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. Control to stop.

  Further, the main control board 300 adds a control for turning on the first BET lamp 25, the second BET lamp 26, and the third BET lamp 27 based on the reception of the medal insertion command from the payout board 350 and the accumulated number indicator 28. Control the display. On the other hand, when the sub-control board 400 receives a medal insertion command from the payout board 350, the sub-control board 400 outputs a sound at the time of medal insertion by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. Take control.

  Further, the main control board 300 performs control to display an error on the stored number display 28 based on the reception of the medal insertion error command from the payout board 350. On the other hand, when the sub-control board 400 receives a medal insertion error command from the payout board 350, the sub-control board 400 performs control to output an error sound from the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. Do.

  Further, the main control board 300 performs control for subtracting and displaying the stored number indicator 28 based on the reception of the BET command from the payout board 350. On the other hand, when receiving a BET command from the payout board 350, the sub control board 400 operates the BET button 7 and the MAXBET button 8 with the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. Control to output the sound of the hour.

  Further, the main control board 300 performs control to repeatedly execute the display determination command reception standby process of the main loop process (see FIG. 28) until the display determination command is received from the payout board 350. That is, the main control board 300 waits until it receives a display determination command from the payout board 350, so that the display determination command is an opportunity to perform subsequent processing. On the other hand, when the sub control board 400 receives the display determination command from the payout board 350, the left upper speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42 cause the left reel 18, the middle reel 19, And a control for outputting a sound when the right reel 20 is stopped, or a control for displaying an effect image when the left reel 18, the middle reel 19 and the right reel 20 are stopped on the liquid crystal display device 45. .

  Further, the main control board 300 performs display control of the stored number display 28 and the payout number display 29 based on the reception of the medal payout start command from the payout board 350. On the other hand, when the sub control board 400 receives a medal payout start command from the payout board 350, the sub-control board 400 outputs a sound at the time of medal payout by the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. Control.

  Further, the main control board 300 performs control to stop the update display of the stored number display device 28 and the payout number display device 29 based on the reception of the medal payout end command from the payout board 350. On the other hand, when the sub control board 400 receives the medal payout end command from the payout board 350, the sub control board 400 outputs the medal payout output from the upper left speaker 39, the lower left speaker 40, the upper right speaker 41, and the lower right speaker 42. Control to stop the sound.

  As described above, in this embodiment, the payout board 350 transmits one command only to the main control board 300, transmits only one command to the sub control board 400, and the main control board 300 and the sub control board 400. May be sent to. Then, the main control board 300 and the sub control board 400 perform processing according to the received command.

(List of switch input signals)
Next, a list of switch input signals will be described with reference to FIG.

  The status board 100 performs processing for transmitting various input signals to the main control board 300 and the payout board 350, but (a) transmits only to the main control board 300 depending on the type of the input signal. An input signal, (b) an input signal transmitted only to the payout board 350, and (c) an input signal transmitted to the main control board 300 and the payout board 350 are defined.

  As shown in FIG. 81, in this embodiment, as an example of an input signal that the status board 100 transmits only to the main control board 300, a start switch input signal, a left stop switch input signal, a middle stop switch input signal, and a right stop Examples include switch input signals and auxiliary storage sensor input signals.

  Here, the main control board 300 performs processing for obtaining a random number value generated by the main random number generator 304 based on the reception of the start switch input signal from the status board 100.

  Further, the main control board 300 performs the stop control of the left reel 18 based on the reception of the left stop switch input signal from the status board 100.

  Further, the main control board 300 performs stop control of the middle reel 19 based on the reception of the middle stop switch input signal from the status board 100.

  Further, the main control board 300 performs the stop control of the right reel 20 based on the reception of the right stop switch input signal from the status board 100.

  Further, the main control board 300 performs control to display on the payout number display 29 that the auxiliary storage is full based on the reception of the auxiliary storage sensor input signal from the status board 100.

  The status board 100 determines that the auxiliary storage 203 is full when the auxiliary storage sensor input signal is transmitted to the payout board 350 and is received by the payout board 350. A command having information indicating that the auxiliary storage 203 is full may be transmitted to the main control board 300. In this case, the main control board 300 receives the command having information indicating that the auxiliary storage 203 is full from the payout board 350, and displays the payout number display 29 by the LED display process in step S212. Control to display that the auxiliary storage 203 is full is performed. By doing so, it is not necessary to determine whether or not the auxiliary storage 203 is full on the main control board 300, so that the processing burden on the main control board 300 can be reduced.

  As shown in FIG. 81, in the present embodiment, as an example of an input signal that the status board 100 transmits only to the payout board 350, a settlement switch input signal, a selector sensor input signal, and a hopper sensor input signal can be cited.

  Here, the payout board 350 performs a process of paying out medals stored in the gaming machine 1 based on the receipt of the payment switch input signal from the status board 100.

  Further, the payout board 350 performs a process of updating the value of the insertion number counter provided in the payout RAM 353 based on the reception of the selector sensor input signal from the status board 100.

  Further, the payout board 350 performs processing for updating the value of the remaining payout number counter provided in the payout RAM 353 based on the reception of the hopper sensor input signal from the status board 100.

  As shown in FIG. 81, in this embodiment, as an example of an input signal that the status board 100 transmits only to the main control board 300 and the payout board 350, a BET switch input signal, a MAXBET switch input signal, a door opening / closing Examples include sensor input signals.

  Here, based on the reception of the BET switch input signal from the status board 100, the main control board 300 performs control during the spinning effect. Specifically, the main control board 300 performs part or all of the left reel 18, the middle reel 19, and the right reel 20 based on the reception of the BET switch input signal when performing the spinning effect. Use the to produce. On the other hand, the payout board 350 performs a process of updating the value of the insertion number counter provided in the payout RAM 353 based on the reception of the BET switch input signal from the status board 100.

  Further, the main control board 300 performs control during the spinning effect based on the reception of the MAXBET switch input signal from the status board 100. Specifically, when the main control board 300 is performing the spinning effect, the main control board 300 receives a MAXBET switch input signal, and a part or all of the left reel 18, the middle reel 19, and the right reel 20 are received. Use the to produce. On the other hand, the payout board 350 performs processing for updating the value of the insertion number counter provided in the payout RAM 353 based on the reception of the MAXBET switch input signal from the status board 100.

  Further, the main control board 300 performs control when the door is opened / closed based on the reception of the door opening / closing sensor input signal from the status board 100. Specifically, when executing the program start process (see FIG. 27), the main control board 300 executes the door close command or the door open command based on the reception of the door open / close sensor input signal. Processing to be transmitted to the control board 400 is performed. On the other hand, the payout board 350 sends a door close command or a door open command to the sub-control board 400 based on the reception of the door open / close sensor input signal from the status board 100 after the program start process (see FIG. 27). Process to send.

  As described above, in the present embodiment, the status board 100 transmits the one input signal only to the main control board 300, the case of transmitting only one input signal to the payout board 350, and the main control board 300 and the payout board 350. May be sent. Then, the main control board 300 and the payout board 350 perform processing according to the received input signal.

(Control command reception processing in the second embodiment)
Next, based on FIG. 82, a second embodiment of the control command receiving process performed by the process of step S210 of FIG. 60 will be described. FIG. 82 is a diagram showing a second embodiment of control command reception processing.

  In the second embodiment, as shown in FIG. 79, a command that the main control board 300 transmits only to the payout board 350, a command that the main control board 300 transmits only to the sub-control board 400, and the main control board 300 Commands to be transmitted to the payout board 350 and the sub-control board 400 are not provided. That is, in the second embodiment, the main control board 300 transmits all commands to the payout board 350 and the sub control board 400. Similarly, the payout board 350 transmits all commands to the main control board 300 and the sub control board 400.

  In the following, description of the same parts as those in the above-described embodiment will be omitted.

(Step S210-15)
In step S210-15, the main CPU 301 performs processing for determining whether or not a command has been received. Specifically, the main CPU 301 performs processing for determining whether or not a command has been received from the payout board 350. If it is determined that a command has been received (step S210-15 = Yes), the process proceeds to step S210-16, and if it is determined that a command has not been received (step S210-15). = No), the subroutine of the control command reception process in the second embodiment is terminated, and the process proceeds to step S211 of the interrupt process.

(Step S210-16)
In step S210-16, the main CPU 301 performs a command determination process. Specifically, the main CPU 301 performs processing for determining whether the command is used on the main control board 300. Here, the main CPU 301 performs an automatic medal insertion command, a settlement start command, a settlement end command, a medal insertion command, a medal insertion error command, a BET command, a display determination command, a medal payout start command, and a medal payout end command from the payout board 350. When the illegal hit command is received, it is determined that the command is used on the main control board 300. Then, when the process of step S210-16 ends, the process proceeds to step S210-17.

(Step S210-17)
In step S210-17, the main CPU 301 performs a process of determining whether or not the command is used on the main control board. Specifically, the main CPU 301 performs processing for determining whether or not the command is used in the main control board 300 as a result of performing the command determination processing in step S210-16. If it is determined that the command is used on the main control board (step S210-17 = Yes), the process proceeds to step S210-18, and it is determined that the command is not used on the main control board. In this case (step S210-17 = No), the control command reception process subroutine in the second embodiment is terminated, and the process proceeds to step S211 of the interrupt process.

(Step S210-18)
In step S210-18, the main CPU 301 performs command information storage processing. Specifically, the main CPU 301 performs processing for specifying a command received by the payout board 350 and storing information relating to the received command in a predetermined area of the main RAM 303. When the process of step S210-18 ends, the control command reception process subroutine in the second embodiment ends, and the process proceeds to step S211 of the interrupt process.

  As described above, in the control command reception process in the second embodiment, whether the payout board 350 is a command to be transmitted only to the main control board 300 by selecting the commands received by the main control board 300. Since there is no need to determine whether or not the command is to be transmitted only to the sub control board 400 or the command to be transmitted to the main control board 300 and the sub control board 400, the payout ROM 352 is not necessary. The capacity of can be reduced.

  In the second embodiment, the main control board 300 selects commands received from the payout board 350, but the present invention is not limited to this. For example, the command received from the payout board 350 by the sub control board 400 may be selected. Accordingly, whether the payout board 350 is a command to be transmitted only to the main control board 300, a command to be transmitted only to the sub control board 400, or to the main control board 300 and the sub control board 400. Since it is not necessary to determine whether or not the command is a command to be transmitted, the capacity of the payout ROM 352 can be reduced.

(Control command transmission processing in the second embodiment)
Next, a second embodiment of the control command transmission process performed by the process of step S211 of FIG. 60 will be described based on FIG. FIG. 83 is a diagram showing a second embodiment of the control command transmission process.

(Step S211-15)
In step S211-15, the main CPU 301 performs door close command transmission processing. Specifically, the main CPU 301 performs a process of transmitting a door close command to the payout board 350 and the sub control board 400. When the process of step S211-15 is completed, the control command transmission process subroutine in the second embodiment is terminated, and the process proceeds to step S212 of the interrupt process.

(Step S211-16)
In step S211-16, the main CPU 301 performs a door open command transmission process. Specifically, the main CPU 301 performs a process of transmitting a door open command to the payout board 350 and the sub control board 400. When the process of step S211-16 ends, the control command transmission process subroutine in the second embodiment ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-17)
In step S211-17, the main CPU 301 performs a reel rotation start acceptance command transmission process. Specifically, the main CPU 301 performs a process of transmitting a reel rotation start acceptance command to the payout board 350 and the sub control board 400. When the process of step S211-17 ends, the control command transmission process subroutine in the second embodiment ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-18)
In step S211-18, the main CPU 301 performs a conditional device command transmission process. Specifically, the main CPU 301 performs processing for transmitting a conditional device command to the payout board 350 and the sub-control board 400. When the process of step S211-18 ends, the control command transmission process subroutine in the second embodiment ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-19)
In step S211-19, the main CPU 301 performs a reel rotation start command transmission process. Specifically, the main CPU 301 performs a process of transmitting a reel rotation start command to the payout board 350 and the sub control board 400. When the process of step S211-19 ends, the control command transmission process subroutine in the second embodiment ends, and the process proceeds to step S212 of the interrupt process.

(Step S211-20)
In step S211-20, the main CPU 301 performs a reel stop command transmission process. Specifically, the main CPU 301 performs a process of transmitting a reel stop command to the payout board 350 and the sub control board 400. When the process of step S211-20 is completed, the control command transmission process subroutine in the second embodiment is terminated, and the process proceeds to step S212 of the interrupt process.

(Step S211-21)
In step S211-21, the main CPU 301 performs illegal hit command transmission processing. Specifically, the main CPU 301 performs processing for transmitting an illegal hit command to the payout board 350 and the sub control board 400. Since the illegal hit error is an error in which the game cannot be continued, when the process of step S211-21 is terminated, the process is terminated without shifting to the interrupt process of FIG.

(Discharged board control command reception process in the second embodiment)
Next, a second embodiment of the payout board control command reception process performed by the process of step S403 of FIG. 71 will be described based on FIG. FIG. 84 is a diagram showing a second embodiment of the payout board control command reception process.

(Step S403-13)
In step S403-13, the payout CPU 351 performs processing for determining whether a command has been received. Specifically, the payout CPU 351 performs processing for determining whether or not a command has been received from the main control board 300. If it is determined that a command has been received (step S403-13 = Yes), the process proceeds to step S403-14. If it is determined that a command has not been received (step S403-13). = No), the payout board control command reception process subroutine in the second embodiment is terminated, and the process proceeds to step S404 of the interruption process in the payout board.

(Step S403-14)
In step S403-14, the payout CPU 351 performs command determination processing. Specifically, the payout CPU 351 performs processing for determining whether the command is used on the payout board 350. Here, when the payout CPU 351 receives a reel rotation start acceptance command, a conditional device command, and a reel stop command from the main control board 300, the payout CPU 351 determines that the command is used on the payout board 350. Then, when the process of step S403-14 ends, the process proceeds to step S403-15.

(Step S403-15)
In step S403-15, the payout CPU 351 performs a process of determining whether or not the command is used on the payout board. Specifically, the payout CPU 351 performs processing for determining whether or not the command is used in the payout board 350 as a result of performing the command determination processing in step S403-15. When it is determined that the command is used on the payout board (step S403-15 = Yes), the process proceeds to step S403-16, and when it is determined that the command is not used on the payout board. (Step S403-15 = No), the payout board control command reception process subroutine in the second embodiment is terminated, and the process proceeds to Step S404 of the payout board interrupt process.

(Step S403-16)
In step S403-16, the payout CPU 351 performs command information storage processing. Specifically, the payout CPU 351 performs processing for specifying a command received by the main control board 300 and storing information related to the received command in a predetermined area of the payout RAM 353. When the process of step S403-16 is completed, the subroutine of the payout board control command reception process in the second embodiment is ended, and the process proceeds to step S404 of the interrupt process in the payout board.

  As described above, in the payout board control command reception process in the second embodiment, is the main control board 300 a command transmitted only to the payout board 350 by selecting the commands received by the payout board 350? It is not necessary to determine whether the command is to be transmitted only to the sub control board 400 or the command to be transmitted to the payout board 350 and the sub control board 400. The capacity of can be reduced.

  In the second embodiment, the payout board 350 selects the commands received from the main control board 300, but the present invention is not limited to this. For example, the command received by the sub control board 400 from the main control board 300 may be selected. As a result, the main control board 300 transmits a command to the payout board 350 or the sub control board 400 as a command to be sent only to the payout board 350 or a command to be sent only to the sub control board 400. Therefore, it is not necessary to determine whether or not the command is to be specified, and the capacity of the main ROM 302 can be reduced.

(Control command transmission processing in the second embodiment)
Next, a second embodiment of the payout board control command transmission process performed by the process of step S404 of FIG. 71 will be described based on FIG. FIG. 85 is a diagram showing a second embodiment of the payout board control command transmission process.

(Step S404-17)
In step S404-17, the payout CPU 351 performs a medal automatic insertion command transmission process. Specifically, the payout CPU 351 performs processing for transmitting an automatic medal insertion command to the main control board 300 and the sub control board 400. When the process of step S404-17 is completed, the subroutine of the payout board control command transmission process in the second embodiment is ended, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-18)
In step S404-18, the payout CPU 351 performs a settlement command transmission process. Specifically, the payout CPU 351 performs processing for transmitting a settlement command to the main control board 300 and the sub control board 400. More specifically, the payout CPU 351 starts the checkout for the main control board 300 and the sub control board 400 when the checkout start command is set in the payout transmission data storage area provided in the payout RAM 353. If the payment completion command is set in the payout transmission data storage area provided in the payout RAM 353, the payment completion command is sent to the main control board 300 and the sub control board 400. Process to send. When the process of step S404-18 is completed, the subroutine of the payout board control command transmission process in the second embodiment is finished, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-19)
In step S404-19, the payout CPU 351 performs medal insertion command transmission processing. Specifically, the payout CPU 351 performs processing for transmitting a medal insertion command to the main control board 300 and the sub control board 400. When the process of step S404-19 ends, the subroutine of the payout board control command transmission process in the second embodiment ends, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-20)
In step S404-20, the payout CPU 351 performs BET command transmission processing. Specifically, the payout CPU 351 performs processing for transmitting a BET command to the main control board 300 and the sub control board 400. When the process of step S404-20 ends, the subroutine of the payout board control command transmission process in the second embodiment ends, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-21)
In step S404-21, the payout CPU 351 performs display determination command transmission processing. Specifically, the payout CPU 351 performs processing for transmitting a display determination command to the main control board 300 and the sub control board 400. When the process of step S404-21 ends, the payout board control command transmission process subroutine in the second embodiment ends, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-22)
In step S404-22, the payout CPU 351 performs a medal payout command transmission process. Specifically, the payout CPU 351 performs processing for transmitting a medal payout command to the main control board 300 and the sub control board 400. More specifically, when the medal payout start command is set in the payout transmission data storage area provided in the payout RAM 353, the payout CPU 351 issues a medal to the main control board 300 and the sub control board 400. When a process for transmitting a payout start command is performed and a medal payout end command is set in the payout transmission data storage area provided in the payout RAM 353, a medal is issued to the main control board 300 and the sub control board 400. A process for transmitting a payout end command is performed. When the process of step S404-22 is completed, the subroutine of the payout board control command transmission process in the second embodiment is finished, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-23)
In step S404-23, the payout CPU 351 performs door command transmission processing. Specifically, the payout CPU 351 performs a process of transmitting a door command to the main control board 300 and the sub control board 400. More specifically, the payout CPU 351 opens the door to the main control board 300 and the sub control board 400 when the door open command is set in the payout transmission data storage area provided in the payout RAM 353. When the door close command is set in the payout transmission data storage area provided in the payout RAM 353, the door close command is sent to the main control board 300 and the sub control board 400. Process to send. When the process of step S404-23 is completed, the subroutine of the payout board control command transmission process in the second embodiment is finished, and the process proceeds to step S405 of the interrupt process in the payout board.

(Step S404-24)
In step S404-24, the payout CPU 351 performs illegal hit command transmission processing. Specifically, the payout CPU 351 performs processing for transmitting an illegal hit command to the main control board 300 and the sub control board 400. When the process of step S404-24 is completed, the payout board control command transmission process subroutine in the second embodiment is finished, and the process proceeds to step S405 of the interruption process in the payout board.

(Modification)
Below, the modification of this embodiment is demonstrated.

  When testing the gaming machine 1, a test signal necessary for testing the performance of the gaming machine 1 may be output from the payout board 350. Here, examples of the test signal include information related to the condition device, information related to the result of the display determination process, information related to the payout of medals, and the like. And the payout board | substrate 350 performs the process which outputs a test signal from the test terminal board provided in the payout board | substrate 350 based on satisfying predetermined conditions. This eliminates the need for the main control board 300 to perform a process of outputting a test signal, so that the load on the main control board 300 can be reduced.

  In the present embodiment, the selector sensor 15s detects that a foreign object has been inserted into the medal slot 6, and determines that an error has occurred by the main control board 300 when it has been detected that a foreign object has been inserted. However, the present invention is not limited to this, and a process for determining an error by the payout board 350 may be performed. This eliminates the need for the main sensor board 300 to detect the foreign matter by the selector sensor 15s, thereby reducing the load on the main control board 300.

  In the present embodiment, the selector sensor 15s detects that the medal inserted into the medal slot 6 has flowed backward, and if the medal inserted into the medal slot 6 has been detected to flow backward, The process for determining that the error is caused by the control board 300 is performed. However, the present invention is not limited to this, and the process for determining whether or not the medal inserted into the medal insertion slot 6 by the payout board 350 is reversed is performed. Good. This eliminates the need for the main control board 300 to perform processing for detecting that the medal inserted into the medal slot 6 has flowed back, so that the load on the main control board 300 can be reduced.

  In the present embodiment, the selector sensor 15s detects that the medal inserted into the medal slot 6 is clogged, and if it is detected that the medal is clogged, the main control board 300 has an error. The determination process is performed. However, the present invention is not limited to this, and a process of determining whether or not a medal inserted into the medal insertion slot 6 by the payout board 350 is clogged may be performed. This eliminates the need for the main control board 300 to detect that the medal inserted into the medal slot 6 is clogged, so that the load on the main control board 300 can be reduced.

  In the present embodiment, the external concentrated terminal board 46 is connected to the main control board 300, but the present invention is not limited to this, and the external concentrated terminal board 46 may be connected to the payout board 350. In this case, the external concentration terminal board 46 (a) when an error is detected by the payout board 350, an error signal for enabling identification of an error detected outside the gaming machine 1, (b ) When it is specified by the payout board 350 that the front door 3 has been opened, a door opening signal for outputting that the front door 3 has been opened outside the gaming machine 1 is output. Also good.

  In the present embodiment, the hopper sensor 202s detects that a foreign object has been input to the hopper sensor 202s, and determines that an error has occurred by the main control board 300 when it is detected that a foreign object has been input. Although processing is performed, the present invention is not limited to this, and processing for determining an error by the payout board 350 may be performed. This eliminates the need for the main control board 300 to detect foreign matter by the hopper sensor 202s, thereby reducing the load on the main control board 300.

  Further, in this embodiment, the hopper sensor 202s detects that the medals paid out by the hopper 202 have flowed backwards, and if it is detected that the medals paid out by the hopper 202 have flowed back, an error is detected by the main control board 300. Although it is assumed that the process of determining that there is, the present invention is not limited to this, and a process of determining whether or not a medal paid out by the hopper 202 by the payout board 350 has flowed back may be performed. This eliminates the need for the main control board 300 to perform the process of detecting that the medals paid out by the hopper 202 have flowed back, so that the load on the main control board 300 can be reduced.

  In the present embodiment, the hopper sensor 202s detects that a medal to be paid out by the hopper 202 is jammed, and determines that an error is detected by the main control board 300 when it is detected that the medal is jammed. However, the present invention is not limited to this, and a process of determining whether or not medals paid out by the hopper 202 by the payout board 350 are jammed may be performed. This eliminates the need for the main control board 300 to detect that the medals to be paid out by the hopper 202 are jammed, thereby reducing the load on the main control board 300.

  In the present embodiment, the main control board 300 performs a set value confirmation process for confirming whether or not the value of the set value storage area provided in the main RAM 303 is normal. Instead, the set value confirmation processing may be performed by the payout board 350. In this case, the payout CPU 351 performs processing for determining whether or not the value of the set value storage area provided in the main RAM 303 is a value within the range of “1” to “6”. As a result, it is not necessary to perform the set value confirmation process on the main control board 300, so that the load on the main control board 300 can be reduced.

  The payout board 350 may perform RAM abnormality confirmation processing for determining whether or not the value stored in the main RAM 303 is normal. In this case, the main CPU 301 is stored in the main RAM 303. Is sent to the payout board 350 as a command, and the payout CPU 351 determines whether or not the value stored in the main RAM 303 is normal based on the reception of the command from the main control board 300. Alternatively, the payout CPU 351 may access the main RAM 303 to perform processing for determining whether or not the value stored in the main RAM 303 is normal. As a result, it is not necessary to perform the RAM abnormality confirmation process on the main control board 300, so that the load on the main control board 300 can be reduced.

  It should be noted that backup abnormality confirmation processing for confirming whether or not the main control board 300 is normally backed up by the payout board 350 may be performed. In this case, the main CPU 301 transmits a value related to backup as a command to the payout board 350, and the payout CPU 351 performs normal backup of the main control board 300 based on receiving the command from the main control board 300. It is preferable to confirm whether or not This eliminates the need to perform backup abnormality confirmation processing on the main control board 300, thereby reducing the load on the main control board 300.

  Note that a process of initializing the soft random number of the main control board 300 may be performed by the payout board 350. In this case, the payout CPU 351 transmits an initialization command for initializing a soft random number to the main control board 300, and the main CPU 301 receives the initialization command from the payout board 350 based on the main CPU 301. It is preferable to initialize the soft random number. This eliminates the need for the main control board 300 to determine the initialization time of the soft random number, so that the load on the main control board 300 can be reduced.

  Thus, according to the present invention, in addition to the main control board 300 that controls the game, when a combination of symbols related to winning is displayed on the active line, the payout board 350 that pays out medals, A sub-control board 400 that controls effects is provided, and bidirectional communication is performed between the main control board 300 and the payout board 350, and unidirectional communication from the payout board 350 to the sub-control board 400 is performed. As a result, since the control for paying out medals conventionally performed by the main control board 300 is performed by the payout board 350, the capacity of the main control board 300 can be reduced. Further, by performing unidirectional communication from the payout board 350 to the sub control board 400, for example, when the payout board 350 detects that the front door 3 is opened, the sub control is performed via the main control board 300. A command having information that the front door 3 has been opened is directly transmitted to the sub-control board 400 without transmitting a command having information that the front door 3 has been opened to the substrate 400. Therefore, the processing when the front door 3 is opened can be performed smoothly. Of course, the command transmitted from the payout board 350 to the sub-control board 400 is not limited to a command having information that the front door 3 has been opened, and any command can be used as long as it has information related to a game. It may be.

  In the present embodiment, the left reel 18, the middle reel 19, and the right reel 20 constitute a reel of the present invention.

  In the present embodiment, the start lever 10, the start switch 10sw, the status board 100, and the main control board 300 constitute start operation detecting means of the present invention.

  In the present embodiment, the main control board 300 that executes the internal lottery process constitutes the winning combination determining means of the present invention.

  In the present embodiment, the left stepping motor 151, the middle stepping motor 152, the right stepping motor 153, the reel control board 150, and the main control board 300 constitute the reel rotation control means of the present invention.

  In the present embodiment, the left stop button 11, the left stop switch 11sw, the middle stop button 12, the middle stop switch 12sw, the right stop button 13, the right stop switch 13sw, the status board 100, and the main control board 300 are included in the present invention. The stop operation detection means is configured.

  In the present embodiment, the main control board 300 that performs processing during reel rotation constitutes the stop control means of the present invention.

  In the present embodiment, the payout board 350 that performs the display determination process constitutes a determination unit of the present invention.

  In the present embodiment, the main control board 300 constitutes the main control board of the present invention.

  In the present embodiment, the payout board 350 constitutes the payout board of the present invention.

  In the present embodiment, the sub control board 400 constitutes a sub control board of the present invention.

  In the present embodiment, a gaming machine used for a spinning machine (slot machine) has been described. However, the gaming machine may be used for a pachinko gaming machine, a sparrow ball gaming machine, or an arrangement ball gaming machine.

1 gaming machine 2 cabinet 3 front door 4 hinge mechanism 5 key hole 6 medal slot 7 BET button 7sw BET switch 8 MAXBET button 8sw MAXBET switch 9 settlement button 9sw settlement switch 10 start lever 10sw start switch 11 left stop button 11sw left stop switch 12 Middle stop button 12sw Middle stop switch 13 Right stop button 13sw Right stop switch 14 Return button 15 Selector 15s Selector sensor 16s Error release sensor 17s Door open / close sensor 18 Left reel 19 Middle reel 20 Right reel 21 Production button 22 Cross key 23 Display window 24 Start lamp 25 1st BET lamp 26 2nd BET lamp 27 3rd BET lamp 28 Stored number display device 29 Discharged number display device 30 Allowable display lamp 31 Replay display Amplifier 32 Bonus display unit 33 ART display unit 34 stop button operation display unit 34L left stop button during operation display unit 34C stop button operation display unit 34R right stop button operation and display unit 35 start lever LED
36 Lumbar panel 37 Receptacle unit 38 Medal payout port 39 Upper left speaker 40 Lower left speaker 41 Upper right speaker 42 Lower right speaker 43 Setting display section 44 Setting change button 44sw Setting change switch 45 Liquid crystal display device 46 External concentration terminal board 47 Setting change Key hole 48sw setting change key switch 100 status board 150 reel control board 151 left stepping motor 152 middle stepping motor 153 right stepping motor 154s left reel sensor 155s middle reel sensor 156s right reel sensor 200 power board 201 power button 201sw power switch 202 hopper 202s Hopper sensor 203 Auxiliary storage 203 s Auxiliary storage sensor 204 Discharge slit 205 Hopper guide member 206 Guide member 207 Dispensing guide member 50 set the switch board 300 the main control board 301 the main CPU
302 Main ROM
303 Main RAM
304 main random number generator 350 payout board 351 payout CPU
352 payout ROM
353 payout RAM
354 Payout random number generator 400 Sub control board 401 Sub CPU
402 Sub ROM
403 Sub RAM
404 Sub-random number generator 450 Backlight relay board 451 Left backlight board 452 Middle backlight board 453 Right backlight board 461 Left backlight 462 Middle backlight 463 Right backlight 500 Amplifier board 550 Production device drive relay board 600 Production control board 601 Production control CPU
602 Production control ROM
603 Production control RAM
604 CGROM
605 Sound source IC
606 Sound source ROM
607 VDP
650 LED control board 651 Top LED board 652 Corner LED board 653 Side LED board 654 Receptacle side LED board 655 Receptacle LED board 661 Corner LED
662 Top LED
663 Side LED
664 saucer side LED
665 Receptacle LED
700 Panel LED Relay Board 701 MAXBET Button LED Board 702 Stop Button LED Board 703 Production Button LED Board 704 Lumbar Panel LED Board 705 Bonus Display LED Board 706 ART Display LED Board 707 Stop Button Operation LED Board 708 Start Lever LED Board 709s Production Button Sensor 710 Cross key board 721 MAXBET button LED
722 Stop button LED
722L Left stop button LED
722C Middle stop button LED
722R Right stop button LED
723 Production Button LED
724 Lumbar panel LED

Claims (1)

A plurality of reels having a plurality of symbols arranged on the circumferential surface;
Start operation detecting means for detecting a start operation by the player;
A winning combination determining means for determining a winning combination based on the detection of the start operation by the start operation detecting means;
Reel rotation control means for controlling the rotation of the plurality of reels based on the detection of the start operation by the start operation detection means;
Stop operation detecting means provided corresponding to each of the plurality of reels, and detecting a stop operation by a player;
Stop control means for stopping the reel being rotated by the reel rotation control means based on the detection of the stop operation by the stop operation detecting means and the winning combination determined by the winning combination determining means. and,
A main control board for controlling the game ,
A payout board that performs control related to payout of game media when it is determined that a combination of predetermined symbols is displayed;
A sub-control board that controls the production,
With
The main control board is
Based on the fact that the reel is stopped by the stop control means, a reel stop command having information relating to the stop of the reel is transmitted to the payout board,
The payout substrate is
Determine whether or not the predetermined symbol combination is displayed based on the fact that the one- way communication to the sub control board is enabled and the reel stop command is received from the main control board. A display determination command having information on the result of the transmission to the main control board,
The main control board is
A gaming machine that performs a process of shifting a gaming state based on receiving the display determination command from the payout board .

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