JP6707579B2 - Amusement machine - Google Patents

Description

The present invention relates to a gaming machine such as a pachi-slot machine.

2. Description of the Related Art Conventionally, gaming machines that update game information according to the progress of the game and can display the game information are known. For example, Patent Document 1 discloses a configuration capable of calculating a payout rate. In the above configuration, the payout rate is updated according to the progress of the game, and the numerical information indicating the size of the payout rate can be displayed on the display of the hall management computer provided outside the gaming machine. ..

JP, 2002-66096, A

In the above conventional technology, since numerical information indicating the size of the game information is displayed, the administrator of the gaming machine can confirm whether or not the current size is the size of the game information. However, some managers may not know the proper size of the game information. In the above case, even if the numerical information is displayed, it is not possible to determine whether or not the size indicated by the numerical information is appropriate. In consideration of the above circumstances, an object of the present invention is to make it easy to recognize whether or not the size of the game information is proper.

In order to solve the above problems, the gaming machine according to the present invention controls the progress of the game and also updates the game information according to the progress of the game, and various electronic components including the game control means. There is mounted on the first surface, can be stored and the particular substrate on which an electronic component is not mounted on the second surface opposite the first surface comprises a lid, a specific substrate as the lid portion and the first surface is facing In addition, the information display sticker for displaying specific information includes a transparent substrate case attached to the lid and a substantially plate-shaped display unit, and does not face the information display sticker on the first surface of the specific substrate . The display unit is provided substantially parallel to the first surface of the specific substrate, and the specific display unit is provided in the vicinity of the specific portion of the outer edge of the first surface. No electronic component is mounted on the first surface located between the specific display means and the specific portion, and the game control means uses the identification information corresponding to the game information and the game information in a predetermined game period. It is possible to automatically display a combination of numerical value information indicating the size of the display on the display unit after the power is turned on, and then display the combination during the progress of the game.

According to the above configuration, the numerical information indicating the size equal to or larger than the threshold value is displayed in the first display mode, and the numerical information indicating the size smaller than the threshold value is the second display mode different from the first display mode. Is displayed. In the above configuration, for example, when the upper limit value of the appropriate size of the game information is adopted as the threshold value of the present invention, if the size of the game information is appropriate, the numerical information is displayed in the first display mode, and the appropriate value is displayed. If the numerical value is equal to or larger than the numerical value, the numerical value information is displayed in the second display mode. Therefore, since it is possible to determine whether the size of the game information is proper or not by the display mode of the numerical information, it becomes easy to recognize whether or not the size of the game information is proper.

By the way, in the configuration in which the game information is displayed on the substantially plate-shaped display unit, there is a problem that an unauthorized electronic component is easily mounted on the lower side of the display unit. In particular, in a configuration in which a seal or the like is attached to the substrate case of the specific substrate, the visibility is blocked by the seal, and it is difficult to visually recognize the lower side of the display unit, so that the above-mentioned problems are likely to become apparent. In consideration of the above circumstances, the present invention provides the specific display means in the vicinity of a specific portion of the outer edge of the surface, and the surface of the surface located between the specific display means and the specific portion has any electronic component. It has a configuration in which no parts are mounted. According to the above configuration, when the specific display means is viewed from the specific portion (outer edge side), the area between the surface of the specific substrate and the specific display means can be directly visually recognized. Therefore, for example, as compared with the configuration in which the specific display means is surrounded by the electronic components, the above-described problem can be suppressed.

According to the present invention, it becomes easy to recognize whether or not the size of the game information is appropriate.

It is a front view of a game machine. It is a figure which shows the internal structure of a cabinet. It is a figure which shows the back surface of a front door. It is a figure showing each symbol arranged on each reel. It is a figure for explaining a symbol display area. It is a figure for demonstrating a main control board. It is a figure for demonstrating a board case. It is a functional block diagram of a game machine. It is a conceptual diagram of a symbol code table. It is a conceptual diagram of a winning area lottery table. It is a conceptual diagram of a winning combination determination table. It is a conceptual diagram of a winning combination regulation table. It is a figure for demonstrating the replay which stops in each stop operation sequence. It is a figure for explaining a bell which stops in each stop operation sequence. It is a conceptual diagram of a transition symbol regulation table. It is a diagram for explaining the transition of the gaming state. It is a conceptual diagram of an instruction determination table. It is a figure for demonstrating each command transmitted from a main control board. It is a conceptual diagram of a spinning drum effect determination table. It is a figure for explaining each storage area. It is a figure for explaining a concrete example of the numerical value memorized by each ring buffer. It is a figure for demonstrating each ratio storage area. It is a figure for demonstrating each display information. It is a figure for demonstrating the display mode of ratio information. It is a figure for demonstrating the display mode of identification information. It is a conceptual diagram of an instruction effect determination table. It is a flowchart of the start-up process of the main CPU. 7 is a flowchart of a setting change process of the main CPU. It is a flowchart of the game control process of the main CPU. 7 is a flowchart of an initial setting process of the main CPU. It is a flowchart of an automatic insertion process of the main CPU. It is a flowchart of a game start pre-processing of the main CPU. It is a flow chart of the insertion medal acceptance processing of the main CPU. It is a flowchart of a BET operation acceptance process of the main CPU. It is a flow chart of settlement operation acceptance processing of the main CPU. It is a flow chart of lottery execution processing of the main CPU. It is a flowchart of an internal lottery process of the main CPU. It is a flowchart of an instruction number determination process of the main CPU. It is a flowchart of a wait process of the main CPU. It is a flow chart of pre-stop processing of the main CPU. It is a conceptual diagram of a priority storage area. 7 is a flowchart of a priority storage process of the main CPU. It is a flow chart of stop control processing of the main CPU. It is a flowchart of a display determination process of the main CPU. It is a flowchart of a hopper drive process of the main CPU. It is a flowchart of a state control process of the main CPU. It is a flowchart of an interrupt process of the main CPU. It is a flow chart of display information control processing of the main CPU. It is a flow chart of a sub starting process of a sub CPU. It is a flowchart of each task of the sub CPU. It is a flow chart of command analysis processing of a sub CPU. It is the flowchart of production control processing of the sub CPU. It is a figure for demonstrating the display information of 2nd Embodiment. It is a figure for demonstrating the dump list of 3rd Embodiment. It is a figure for demonstrating the main indicator mounted in the main control board of a modification.

<First Embodiment>
Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the drawings.
<Structure of gaming machine>
The structure of the gaming machine 1 according to the first embodiment will be described with reference to FIGS. 1 to 3. FIG. 1 is an example of a front view of the gaming machine 1. A player plays a game on the gaming machine 1 using a game medium (for example, a medal or a game ball). In the present embodiment, a gaming machine 1 (pachi-slot machine) in which medals are used as a game medium is exemplified.

The gaming machine 1 is configured to include a box-shaped cabinet 2 having an opening on the front side (player side) and a front door 3. FIG. 2 is a diagram showing an example of the internal structure of the cabinet 2. Further, FIG. 3 is an example of a front view of the back surface of the front door 3 (the surface on the inner side of the gaming machine 1). As shown in FIG. 2, the cabinet 2 is provided with a hinge mechanism 2a. The front door 3 is pivotally supported by the hinge mechanism 2a so that the opening of the cabinet 2 can be opened and closed.

As shown in FIG. 1, a plurality of (14 in the example of FIG. 1) housing lamps 5 are provided on the peripheral side of the front door 3. Each housing lamp 5 is composed of, for example, a light emitting body such as a light emitting diode (Light Emitting Diode) and a light transmissive lens that covers the light emitting body. The housing lamp 5 emits light in a mode according to each effect in the gaming machine 1.

As shown in FIG. 1, a waist panel 6 is provided on the front door 3. On the waist panel 6, the name of the game machine 1 and the like are drawn. Further, inside the gaming machine 1 (front door 3), a light emitter that illuminates the waist panel 6 is provided. As the light emitter for illuminating the waist panel 6, for example, a light emitting diode or a cold cathode tube is adopted. A saucer unit 7 that stores medals is provided below the waist panel 6. The tray unit 7 is provided so that the player can freely take out the stored medals.

The front door 3 is provided with a medal insertion portion 8 having an opening through which medals are inserted, and a medal payout opening 9 through which medals are discharged from the inside of the gaming machine 1. When a specified number (3) of medals are inserted from the medal insertion section 8, the game can be started. The specified number is set according to the state of the game. The medals discharged from the medal payout opening 9 are stored in the tray unit 7.

A panel 10 is provided on the center side of the front surface of the front door 3. A substantially rectangular display window 11 is formed in the center of the panel 10. Through the display window 11, the plurality of reels 12 (12L, 12C, 12R) inside the cabinet 2 can be viewed.

Each reel 12 is configured to include a substantially cylindrical drum portion and a belt-shaped sheet member mounted on the outer peripheral surface of the drum portion. The sheet member of the reel 12 is light transmissive, and a plurality of types of designs are drawn. Each reel 12 is rotatably provided and, as shown in FIG. 2, is arranged horizontally adjacent to each other. Specifically, the reels 12 are arranged such that the rotation axes are located on the same straight line. In addition, each reel 12 is fixed to the reel support 12F. A stepping motor 101 (101L, 101C, 101R) is provided on each reel 12 (not shown), and each reel 12 is rotated by each stepping motor 101.

FIG. 4 is a diagram showing each symbol arranged on each reel 12 of the present embodiment. As shown in FIG. 4, the outer circumference of each of the plurality of reels 12 is divided into 21 frames. As shown in FIG. 4, one pattern is drawn on each frame. In this embodiment, the Nth frame (N is an integer from the numerical value “0” to the numerical value “20”) from the bottom of the symbol array shown in FIG. 4 may be described as the symbol position “N”. As shown in FIG. 4, on each reel 12, a bell symbol, a star bell symbol, a plum symbol, a replay x symbol, a replay y symbol, a red seven symbol, a black BAR symbol, a white BAR symbol, a watermelon symbol and a cherry symbol are arranged. To be done. Specifically, the bell symbol is a symbol position “3, 8, 17” of the left reel 12L, a symbol position “1, 4, 9, 12, 17” of the middle reel 12C, and a symbol position of the right reel 12R “. 4, 7, 12, 15, 20". The star bell symbol is arranged at the symbol position "13, 20" on the left reel 12L. The plum symbols are symbol positions "1, 6, 9, 15, 18" on the left reel 12L, symbol positions "0, 3, 8, 11" on the middle reel 12C, and symbol positions "3, 6" on the right reel 12R. , 11, 14”. The replay x symbol is a symbol position "2, 12, 16, 19" of the left reel 12L, a symbol position "2, 7, 10, 15, 20" of the middle reel 12C, and a symbol position "0, of the right reel 12R. 16, 18". The replay y symbols are arranged at the symbol position "7" of the left reel 12L and the symbol position "5, 8, 13" of the right reel 12R. The red seven symbols are arranged in the symbol position "5" of the left reel 12L, the symbol positions "5, 18" of the middle reel 12C, and the symbol position "10" of the right reel 12R. The black BAR symbols are arranged at the symbol position "4" of the left reel 12L, the symbol position "14" of the middle reel 12C, and the symbol position "2" of the right reel 12R. The white BAR symbols are arranged at the symbol position "11" of the left reel 12L, the symbol position "16" of the middle reel 12C, and the symbol position "19" of the right reel 12R. The cherry symbols are arranged at the symbol position "10" of the left reel 12L, the symbol position "6, 19" of the middle reel 12C, and the symbol position "9, 17" of the right reel 12R. The watermelon symbols are arranged at the symbol position "0, 14" of the left reel 12L, the symbol position "13" of the middle reel 12C, and the symbol position "1" of the right reel 12R. A symbol arrangement table showing the arrangement of symbols on each reel 12 is stored in the main ROM 302.

In the display window 11 of the front door 3 shown in FIG. 1, three symbols are stopped and displayed for each reel 12. That is, when all the reels 12 are stopped, a total of nine symbols are stopped and displayed on the display window 11. In the present embodiment, the area where each symbol is displayed is referred to as a “symbol display area”.

FIG. 5 is a diagram for explaining the symbol display area. As shown in FIG. 5, the symbol display area includes each unit area U (L, C, R). One symbol is displayed in each of the unit areas U. Each unit area U is a unit area UL in which each symbol of the left reel 12L is displayed, each unit area UC in which each symbol of the middle reel 12C is displayed, and each unit in which each symbol of the right reel 12R is displayed. And a region UR. Each unit area UL includes a unit area UL1 located at the upper level, a unit area UL2 located at the middle level, and a unit area UL3 located at the lower level. In addition, each unit area UC includes a unit area UC1 located at the upper level, a unit area UC2 located at the middle level, and a unit area UC3 located at the lower level, and each unit area UR includes a unit area UR1 located at the upper level and a middle area. The unit area UR2 located in the lower part and the unit area UR3 located in the lower part are included.

When a specified number of medals have been inserted into the medal insertion section 8, an effective line is set. The effective line is constituted by one unit area U of the reel 12L, one unit area U of the reel 12C, and one unit area U of the reel 12R among the unit areas U. Area. The effective line of the present embodiment is a line connecting the unit area UL2 of the reel 12L, the unit area UC2 of the reel 12C, and the unit area UR2 of the reel 12R.

A combination of symbols as a result of the game is stopped and displayed on the activated line. When a predetermined combination of symbols is stopped on the activated line, a profit is given to the player according to the stopped combination of symbols. For example, when a winning combination of symbols is stopped and displayed on the activated line, a medal is awarded to the player. Further, when the combination of symbols relating to the replay is stopped and displayed on the activated line, the right to replay is given to the player. Specifically, when a combination of symbols relating to a re-play is displayed in this game, the next game can be started without the need to insert medals. The combination of symbols that can be stopped and displayed on the activated line is determined for each game according to the result of the internal lottery processing described later.

In the present embodiment, a line that connects the upper unit area UL1 of the reel 12L, the upper unit area UC1 of the reel 12C and the upper unit area UR1 of the reel 12R may be referred to as an “upper line”. Similarly, a line (an effective line of the present embodiment) that connects the middle unit area UL2 of the reel 12L, the middle unit area UC2 of the reel 12C, and the middle unit area UR2 of the reel 12R may be referred to as a “middle line”. is there. Further, a line connecting the lower unit area UL3 of the reel 12L, the lower unit area UC3 of the reel 12C and the lower unit area UR3 of the reel 12R may be referred to as a “lower line”. A line connecting the lower unit area UL3 of the reel 12L, the middle unit area UC2 of the reel 12C, and the upper unit area UR1 of the reel 12R may be referred to as an “upper right line”. Similarly, a line connecting the upper unit area UL1 of the reel 12L, the middle unit area UC2 of the reel 12C, and the lower unit area UR3 of the reel 12R may be referred to as a "right downward line".

Further, each reel 12 is provided with each backlight that illuminates the sheet member of the reel 12 from the inside (not shown). Specifically, each of the reels 12 has a backlight that illuminates the unit area U of the upper line of the reel 12, a backlight that illuminates the unit area U of the middle line, and a backlight that illuminates the unit area U of the lower line. It is provided.

As shown in FIG. 1, the panel 10 has an insertable display lamp 13, a BET lamp 14 (14a, 14b, 14c), a start lamp 15, an instruction display 16, a stored number display 17, a replay display lamp 18, A plurality of indicators (hereinafter referred to as “indicators ML”) including a weight lamp 19 and a stop lamp 20 are provided. Each lamp of the display ML is controlled by the main CPU 301 described later.

The insertable display lamp 13 notifies whether or not it is in a state in which it is possible to receive medals from the medal inserting section 8. Specifically, in a state in which it is possible to receive medals from the medal insertion portion 8, the insertable display lamp 13 lights up. On the other hand, when the medal cannot be accepted, the insertable display lamp 13 is turned off. For example, while the reel 12 is rotating, since the medal cannot be received, the insertable display lamp 13 is turned off. On the other hand, when all the reels 12 are stopped and the medal can be received, the throwable indicator lamp 13 is turned on.

The BET lamp 14 displays the number of bet medals. Further, the BET lamp 14 includes a one-sheet lamp 14a, a two-sheet lamp 14b, and a three-sheet lamp 14c. When one bet medal is set, the one-lamp 14a lights up, when two bet medals are set, the one-lamp 14a and the two-lamp 14b light up, and three bet medals are set. Then, the single lamp 14a, the double lamp 14b, and the triple lamp 14c are turned on. The start lamp 15 informs whether or not it is possible to accept a game start operation (operation of a start lever 24 described later). Specifically, the start lamp 15 is turned on when a specified number of betting medals are set or when a combination of symbols relating to a replay is stopped on the activated line.

The instruction display device 16 is controlled by the main CPU 301 and displays instruction information for instructing the operation mode (push order) of the stop button 25. As will be described later in detail, the main CPU 301 causes the instruction display device 16 to display instruction information in each game in the AT state. Further, when the symbol combination related to the winning combination is displayed on the activated line, the instruction display unit 16 displays the number of medals given to the player. For example, when the symbol combination "bell-bell-bell" is stopped and displayed on the activated line, nine medals are awarded to the player, and the instruction display device 16 displays the number "9". The instruction indicator 16 of the present embodiment is a one-digit 7-segment display.

The number of medals given to the player can be electrically stored (stored) in the gaming machine 1 (main RAM 303 described later). In the present embodiment, the number of stored medals is referred to as “credit count”. The number of credits is added when medals are awarded as a result of the game. Further, the credit amount is added when a specified number of betting medals have been inserted and further medals have been inserted from the medal insertion unit 8.

The stored number display unit 17 displays the number of credits. Specifically, the stored number display 17 variably displays a value from “0” to a value “50” which is the upper limit value of the credit number according to the stored credit number. The replay display lamp 18 notifies that the replay is in progress. Specifically, the re-game display lamp 18 is lit until the next game ends after the combination of symbols relating to the re-game in this game is stopped and displayed on the activated line. By turning on the re-play display lamp 18, the player is notified that the next game start operation can be performed without using medals. The weight lamp 19 is lit during a wait period from when a game start operation (operation of a start lever 24 described later) is performed until rotation of each reel 12 is started. The wait period is provided to set the average time length required for one game to a predetermined value (about 4.1 seconds) or more. The stop lamp 20 informs that the game is in a stop state where the game is impossible.

As shown in FIG. 1, the front door 3 has a 1BET button 21, a MAX-BET button 22, a settlement button 23, a start lever 24, a plurality of stop buttons 25 (25L, 25C, 25R), an effect button 26 and direction designation. A plurality of operation units including a button 27 are provided. Each operation unit is operated by the player.

The 1 BET button 21 is operated when setting one bet medal using the stored medals. For example, if the 1-BET button 21 is operated with no bet medal set, the number “1” is subtracted from the number of credits, and one bet medal is set. That is, the player can set one bet medal by using the stored medals by operating the 1 BET button 21. The MAX-BET button 22 is operated when setting a specified number of betting medals using the stored medals. For example, when the MAX-BET button 22 is operated with no bet medals set, 3 (the specified number) is subtracted from the credit amount, and 3 bet medals are set. The settlement button 23 is operated when the medals and betting medals stored as the number of credits are settled. When the settlement button 23 is operated, the total number of credits and betting medals is paid out from the medal payout opening 9. The betting medals may be settled by the first operation of the settlement button 23, and the credits may be settled by the second operation. In this embodiment, the operation of the MAX-BET button 22 or the 1-BET button 21 may be referred to as a BET operation.

The start lever 24 is operated by the player when starting a game. The player can instruct the start of the game by performing a start operation on the start lever 24 while the game can be started. The start lever 24 of this embodiment can be tilted in any direction of 360 degrees from a state substantially vertical to the front door 3. Further, the ball grip portion of the start lever 24 is formed of a translucent resin and has a lever effect lamp 42 built therein. The lever effect lamp 42 lights up in a predetermined effect.

The stop button 25 is operated by the player when stopping the reel 12. Further, the stop button 25 includes a stop button 25L, a stop button 25C and a stop button 25R. The stop button 25L corresponds to the reel 12L, the stop button 25C corresponds to the reel 12C, and the stop button 25R corresponds to the reel 12R. When the stop button 25 corresponding to the reel 12 is operated (hereinafter referred to as “stop operation”) while the reel 12 is rotating, the reel 12 is stopped.

Hereinafter, in this embodiment, the first stop operation in each game is called a first stop operation. Similarly, the second stop operation is called the second stop operation, and the third stop operation is called the third stop operation. Further, the control in which the gaming machine 1 (main CPU 301, which will be described later) stops the reel 12 based on the first stop operation is referred to as first stop control. Similarly, stop control of the reel 12 based on the second stop operation is referred to as second stop control, and stop control of the reel 12 based on the third stop operation is referred to as third stop control. Further, the symbol position of the reel 12 located in the middle line of the display window 11 at the time when the stop operation is performed is referred to as a stop operation position. The symbol position located in the middle line during the rotation of each reel 12 is stored in the symbol counter, and the symbol position of the symbol counter at the time of the stop operation is acquired as the stop operation position. The symbol counter is provided in the main RAM 303, for example.

When all the reels 12 are stopped, a combination of symbols as a result of the game is displayed on the activated line, and the game ends. As will be described later, when the game is started, each reel 12 is accelerated to a constant rotation speed. During a period in which each reel 12 has a constant rotation speed (a period in which the reel 12 is steadily rotating), a stop operation for stopping and displaying the result of the game on the activated line becomes possible. On the other hand, during the acceleration period from the start of rotation of each reel 12 to the steady rotation, the stop operation for displaying the result of the game is not accepted even if the reel 12 is rotating.

The effect button 26 is operated by the player when giving an instruction regarding effect. For example, the user can instruct execution of a specific effect by operating the effect button 26. That is, the specific effect is executed when the operation of the effect button 26 is triggered. Note that the MAX-BET button 22 can also have the function of the effect button 26. According to the above configuration, the effect button 26 is omitted, and the number of parts can be reduced.

The direction designation button 27 is operated by the player, for example, when the menu image is displayed on the liquid crystal display device 30. The direction designation button 27 includes an up button, a down button, a right button, and a left button. For example, by operating the direction designating button 27, the cursor designating the options displayed in the menu image can be moved. Specifically, when the up button is operated, the cursor in the menu image moves upward. Similarly, when the down button is operated, the cursor moves downward, when the right button is operated, the cursor moves right, and when the left button is operated, the cursor moves left. When the direction designation button 27 is operated in the non-gaming state, the master volume of the gaming machine 1 is changed.

As shown in FIG. 1, on the panel 10 of the front door 3, in addition to the display ML (start lamp 15 and the like) described above, a plurality of effect lamps 28 (28a to 28e) and a plurality of stop operation sequence display lamps 29 are provided. (29L, 29C, 29R) are provided. Each lamp of the display ML is controlled by the main CPU 301, while each effect lamp 28 and each stop operation sequence display lamp 29 are controlled by the sub CPU 412 described later. The effect lamps 28a and the effect lamps 28b among the plurality of effect lamps 28 are provided on the left side of the display window 11 in the front view, and the effect lamps 28c to 28e are the right side of the display window 11 in the front view. It is provided in. Each effect lamp 28 reports the current state of the game and the like.

Each stop operation order display lamp 29 is provided in a region of the panel 10 below the display window 11, and notifies the operation order of each stop button 25. Specifically, the stop operation sequence display lamp 29L is provided at a position corresponding to the reel 12L (lower left side of the display window 11), and the stop operation sequence display lamp 29C is provided at a position corresponding to the reel 12C (display window 11). The stop operation order display lamp 29R is provided at the center lower side) and is provided at a position (the lower right side of the display window 11) corresponding to the reel 12R. For example, it is assumed that the player is informed of the order (so-called reverse push) of the stop button 25R by the first stop operation, the stop button 25C by the second stop operation, and the stop button 25L by the third stop operation. In the above case, the stop operation sequence display lamp 29R lights up when the game is started, the stop operation sequence display lamp 29C lights up after the stop button 25R is operated, and the stop operation sequence after the stop button 25C is operated. The display lamp 29L lights up.

As shown in FIG. 1, a liquid crystal display device 30 for displaying various images is provided above the display window 11 of the front door 3. The liquid crystal display device 30 displays a moving image and a still image according to the effect executed by the gaming machine 1. Specifically, the liquid crystal display device 30 notifies information related to a result of an internal lottery process described later, information indicating a gaming state, and the like.

As shown in FIG. 1, an upper lamp 35 (L, R) is provided on the upper end side of the front door 3. The upper lamp 35 is configured to include, for example, a light emitting diode that can emit light of each color (blue, yellow, green, red, etc.) and a lens that covers the light emitting diode. For example, when the winning combination is stopped and displayed on the activated line, the upper lamp 35 emits light in a mode (color) corresponding to the winning combination. Moreover, the upper lamp 35 emits light in each effect in a manner according to the effect.

As shown in FIGS. 1 and 3, the front door 3 is provided with speakers 31 (31L, 31R) and speakers 32 (32L, 32R). The speaker 31 is provided on the lower end side of the front door 3, and includes a speaker 31L attached to the left side and a speaker 31R attached to the right side when viewed from the player side. Further, the speaker 32 is provided on the upper end side of the front door 3, and includes a speaker 32L attached to the left side and a speaker 32R attached to the right side when viewed from the player side. The speaker 31 and the speaker 32 output sounds (music, voice, and sound effects) according to the effect. For example, the speaker 31 and the speaker 32 output the sound related to the performance performed by the liquid crystal display device 30, the effect lamp 28, the housing lamp 5, the stop operation sequence display lamp 29, or the lever effect lamp 42 described above. To do. The speaker 31 and the speaker 32 are attached to the back surface of the front door 3, and a plurality of sound emission holes are formed on the surface of the front door 3 at positions corresponding to the speaker 31 and the speaker 32, respectively.

As shown in FIG. 1, a return button 33 is provided on the front door 3. The return button 33 is operated to clear the clogging of medals in the medal flow path inside the gaming machine 1. By operating the return button 33, the medals clogging the medal flow path are ejected from the medal payout opening 9.

The front door 3 is provided with a locking device 4 having a keyhole. The front door 3 is locked by engaging the locking device (not shown) of the cabinet 2 with the locking device 4 of the front door 3. As shown in FIG. 1, the keyhole of the locking device 4 is located on the front surface of the front door 3, and a key (not shown) for unlocking the front door 3 can be inserted. As will be described later, various operation parts (for example, setting change button 37) are provided inside the cabinet 2. Each operation unit inside the cabinet 2 is operated by an administrator of a key that unlocks the front door 3 (for example, a clerk of a game hall where the gaming machine 1 is installed).

As shown in FIG. 3, on the back surface of the front door 3, a selector 34 that can switch the flow path of the medals inserted from the medal insertion portion 8 is provided. Specifically, the selector 34 includes a solenoid (not shown), and the medal flow path is switched according to the ON/OFF state of the solenoid. Further, the ON/OFF state of the solenoid is changed depending on whether or not the insertion of medals is permitted. For example, when the insertion of medals is permitted, the solenoid of the selector 34 is in the ON state, and the selector 34 guides the medals inserted from the medal insertion portion 8 into the game machine 1. As shown in FIG. 3, an inserted medal guide member 522 is provided near the right side of the selector 34 when viewed from the inside of the gaming machine 1. The inserted medal guide member 522 guides the medals that have passed through the selector 34 to the hopper 520 provided inside the cabinet 2.

On the other hand, when the insertion of medals is not permitted (for example, when the reel 12 is rotating), the solenoid of the selector 34 is in the OFF state, and the selector 34 inserts the medals inserted from the medal insertion unit 8 into the gaming machine. Lead to the outside of 1. Further, the selector 34 guides the foreign matter (for example, an illegal medal) inserted from the medal insertion unit 8 to the outside of the gaming machine 1, even when the insertion of medals is permitted. As shown in FIG. 3, a discharged medal guide member 523 is provided near the lower side of the selector 34. The ejected medal guide member 523 guides the medal or the like from the selector 34 to the medal payout opening 9 on the front side of the front door 3.

As shown in FIG. 2, a hopper 520 having a tank portion 521a for storing medals and having a discharge slit 521b for discharging medals is provided inside the cabinet 2. The medals inserted from the medal insertion portion 8 are stored in the tank portion 521a, and the medals stored in the tank portion 521a are paid out to the tray unit 7 from the discharge slit 521b through the medal payout opening 9. For example, the hopper 520 pays out medals when a winning combination of symbols is displayed on the activated line or when the settlement button 23 is operated.

As shown in FIG. 3, a payout medal guide member 524 is provided on the back surface of the front door 3. The payout medal guide member 524 guides the medals from the hopper 520 to the medal payout opening 9. Specifically, the payout medal guide member 524 has an opening, and the opening faces the discharge slit 521b of the hopper 520 when the front door 3 is closed. The medals discharged from the discharge slit 521b enter the opening of the payout medal guide member 524, and are guided to the medal payout opening 9 by the payout medal guide member 524.

As shown in FIG. 2, an auxiliary storage section 530 is provided inside the cabinet 2. The auxiliary storage unit 530 stores medals overflowing from the hopper 520. It is also possible to provide a hole that penetrates the bottom of the auxiliary storage unit 530 and the bottom of the cabinet 2 and discharge the medals overflowing from the hopper to the outside of the gaming machine 1 through the hole.

As shown in FIG. 2, a main control board 300 is provided inside the cabinet 2. Specifically, the main control board 300 is housed in a transparent board case 600 and attached to the back plate of the cabinet 2. Various electronic components including a main CPU 301 described later are mounted on the main control board 300. The main control board 300 is electrically connected to various boards including a reel board 100, a relay board 200, a sub control board 400, and a power supply board 500, which will be described later, via connectors (not shown). In addition, the various substrates described above may be configured by a single substrate or may be configured by a plurality of substrates.

As shown in FIG. 2, a setting display section 36 and a setting change button 37 are provided inside the cabinet 2. The setting display unit 36 displays the set value of the gaming machine 1. The set value is a numerical value related to the payout rate of the gaming machine 1, and various lottery is executed with a probability according to the set value in each game. For example, the set values are set from "1" to "6", and the set value "6" has the highest payout rate. In this embodiment, when the setting change key is inserted into the key hole for changing the setting and rotated, the setting display unit 36 displays the set value.

The setting change button 37 is operated when changing the numerical value of the setting display unit 36. The setting display unit 36 adds and displays one numerical value each time the setting change button 37 is operated. For example, when the setting change button 37 is operated while the numerical value “1” is displayed on the setting display unit 36, the numerical value “2” is displayed on the setting display unit 36. However, when the setting change button 37 is operated while the numerical value “6” is displayed on the setting display unit 36, the numerical value “1” is displayed on the setting display unit 36. When the start lever 24 is operated while the set value is displayed on the setting display unit 36, the numerical value displayed on the setting display unit 36 at the time of the operation is stored as the set value.

As shown in FIG. 3, a sub control board 400 is provided on the back surface of the front door 3. The sub control board 400 is configured to include various boards including an effect control board 410, an image control board 420, and a sound board 430.

As shown in FIG. 2, a power supply device 510 is provided inside the cabinet 2. The power supply device 510 includes an AC-DC converter and a DC-DC converter (both not shown), generates a DC voltage from an AC voltage supplied from the outside of the gaming machine 1, and generates a plurality of types of DC voltage from the generated DC voltage. Generates DC voltage. For example, the power supply device 510 includes a DC voltage of 32V used to drive a motor and a solenoid, a DC voltage of 12V supplied to the liquid crystal display device 30, and a 5V voltage supplied to an electronic circuit board (for example, the main control board 300). And a DC voltage of.

As shown in FIG. 2, the power supply device 510 is provided with a power button 511 and a reset button 512. When the power button 511 is operated in the ON state, power is supplied to the gaming machine 1, and when the power button 511 is operated in the OFF state, the power is cut off. The reset button 512 is operated when resetting a game state or the like. Specifically, when the reset button is operated, a predetermined storage area of the main RAM 303 described later is reset to the initial value.

As shown in FIG. 2, the power supply device 510 is provided with a shielding plate 513. The shield plate 513 is located on the front side of the power button 511 and the reset button 512. Further, the shield plate 513 can be moved to a position where the power button 511 and the reset button 512 are shielded and a position where the reset button 512 is not shielded. Specifically, when the front door 3 is closed, the shielding plate 513 shields the power button 511 and the reset button 512. According to the above configuration, for example, an illegal act of inserting a wire from the outside of the gaming machine 1 into the sound output hole of the speaker 31 and operating the power button 511 or the reset button 512 inside the gaming machine 1 is suppressed.

FIG. 6A is a front view of the main control board 300 described above. The sub-board 700 is housed in the board case 600 together with the main control board 300. The sub board 700 is electrically connected to the main control board 300 by a connector CNx. Further, as shown in FIG. 6A, the sub-board 700 is provided with a keyhole K and a setting change button 37. By inserting the setting change key into the keyhole K and rotating it, the set value of the gaming machine 1 can be changed. When the set value can be changed, any one of the set values (1 to 6) is displayed on the setting display section 36, and the set value on the setting display section 36 can be changed by operating the setting change button 37. You can

As shown in FIG. 6A, various electronic components (R, C, IC, CN) are provided on the main control board 300. Specifically, the chip IC (including the main CPU 301, the main ROM 302, and the main RAM 303), the resistor R, the capacitor C, the connectors CN (a to c) including the above-mentioned connector CNx, the setting display unit 36, and the main display 40. Various electronic components including are mounted on the main control board 300. The connector CN is used to electrically connect the main control board 300 to another control device.

As described above, the main control board 300 is housed in the board case 600 and attached to the back plate of the cabinet 2 substantially in parallel. FIG. 6A is a front view of a surface (front surface) of each surface of the main control board 300 on the opposite side (player side) to the back plate of the cabinet 2. In this embodiment, in order to easily confirm whether or not an unauthorized electronic component is attached to the main control board 300, the substrate case 600 is made of a transparent resin, and the electronic component is provided only on the surface of the main control board 300. Is mounted (electronic parts are not mounted on the back surface).

Further, in order to make it easy to visually confirm whether or not each electronic component of the main control board 300 is replaced with an unauthorized electronic component, each electronic component having a surface area larger than approximately 6 mm 2 is adopted. As shown in FIG. 6A, the manufacturer name of the gaming machine 1 is displayed on the main control board 300. Further, on the main control board 300, a model identifier capable of specifying the model name of the gaming machine 1 is displayed.

As shown in FIG. 6A, the main display 40 is provided near the upper edge E of the main control board 300. The main CPU 301 calculates various game information (bonus ratio, BB ratio, latest bonus ratio, latest BB ratio, regulation period ratio) according to the progress of the game, and the main display 40 displays the display information according to the game information. To display. The display information includes identification information corresponding to each game information and ratio information indicating the size of the game information.

Temporarily, a board on which the main CPU 301 is mounted (hereinafter “first board”) and a board on which the main display 40 is mounted (hereinafter “second board”) are separately provided, and the main display 40 displays game information. Assume proportionality. A signal capable of specifying game information is transmitted from the first board to the second board. In the above-described contrast, it is possible to perform an illegal act of interposing an illegal device between the first substrate and the second substrate and transmitting a signal for displaying game information different from the actual one to the second substrate. In consideration of the above circumstances, in the present embodiment, the main display 40 (specific display means) for displaying the game information is the same board (specific board) as the main CPU 301 (game control means) for updating the game information. Will be implemented in. Therefore, there is an effect that the above-mentioned fraudulent behavior is suppressed as compared with the proportionality.

As shown in FIG. 6B, the main display 40 includes a first display section 40X and a second display section 40Y. The first display section 40X displays the identification information described above. The second display unit 40Y also displays the above-mentioned ratio information. When the power of the gaming machine 1 is turned on, the main display 40 starts displaying the display information and then continues until the power is turned off. As will be described later in detail, the main display 40 displays a plurality of display information corresponding to various game information. Each display information is switched and displayed at a predetermined time interval (about 5 seconds).

FIG. 6B is a front view of the main display 40 among the electronic components of the main control board 300. As shown in FIG. 6B, the main display 40 is composed of four 7-segment displays. Specifically, of the main display 40, the first display section 40X is composed of two 7-segment displays, and the second display section 40Y is composed of two 7-segment displays. Each 7-segment display of the main display 40 is arranged in the left-right direction as shown in FIG.

FIG. 6C is a perspective view of a 7-segment display that constitutes the main display 40. As shown in FIG. 6C, each 7-segment display includes a display section and a plurality of pin sections. The display unit causes the eight light emitting elements (segments) to emit light, so that the numbers “0” to “9” and various characters (for example, the characters “A”, “Y”, “U”, see FIG. 23). And display the decimal point. The above 7-segment display is mounted on the main control board 300 by a well-known technique, and each pin portion is electrically connected to the main control board 300.

The description is returned to FIG. In each of the 7-segment displays of the main display 40 of the present embodiment, the areas of the display section on which the respective segments are provided (hereinafter referred to as “display surface”) have substantially the same area. As shown in FIG. 6B, each display surface of each 7-segment display is substantially rectangular, and the horizontal lengths of the display surfaces of each 7-segment display are substantially equal. The vertical length of the display surface of each 7-segment display is substantially equal. Specifically, the display surface of each 7-segment display is a substantially rectangular shape having a horizontal length of A mm (millimeter) and a vertical length of B mm.

The area of the display surface of the 7-segment display of the main display 40 is equal to or larger than a predetermined threshold value. Specifically, the area of the display surface of one 7-segment display is 36 mm 2 or more. For example, a 7-segment display having a display surface with a vertical length of about 7.5 mm, a horizontal length of about 4.8 mm, and an area of about 36 mm 2 is suitable. In the above case, the total area of the display surfaces of the main display 40 (four 7-segment displays) is about 144 (36×4) mm 2. According to the above configuration, compared to the configuration in which the area of the display surface of the 7-segment display of the main display unit 40 is less than 36 mm 2, there is an advantage that various information displayed by the main display unit 40 is easily visible.

FIG. 6D is a diagram for explaining a state where the main display 40 is mounted on the main control board 300. FIG. 6D assumes that the main display 40 is viewed from a direction horizontal to the surface of the main control board 300. Specifically, FIG. 6D assumes a case where the main display 40 is viewed in the horizontal direction from the upper edge E (see FIG. 6A) side of the main control board 300. As shown in FIG. 6D, when the main display 40 is mounted on the main control board 300, one end of the display section and the pin section on the display section side (upper side) is located on the surface of the main control board 300. The other end of the pin portion is connected to the main control board 300.

By the way, conventionally, when an electronic component having a relatively large area is mounted on the main control board 300, an unauthorized electronic component is provided between the surface of the main control board 300 and the electronic component (below the electronic component). The fraud to be implemented is known. As described above, in order to improve the visibility of each game information displayed on the main display device 40, the area of the display surface of the main display device 40 of the present embodiment is a predetermined threshold value (36 mm2) or more. Therefore, the inconvenience that the above-mentioned fraudulent acts become easy is assumed.

In consideration of the above circumstances, in the present embodiment, it is difficult (substantially impossible) to mount another electronic component between the main display 40 (each 7-segment display) and the surface of the main control board 300. did. Specifically, as can be understood from FIG. 6D, the main display 40 is mounted so as to be close to the surface of the main control board 300 (without causing a large gap). For example, it is preferable that the distance between the display unit of the main display 40 and the main control board 300 is 3 mm or less. According to the above configuration, the above-mentioned inconvenience is suppressed.

Further, as shown in FIG. 6A, no electronic component is mounted on the surface of the main control board 300 from the upper edge E to the area where the main display 40 is provided. Therefore, when viewed from the upper edge E side, as shown in FIG. 6D, the main display 40 does not overlap with other electronic components. Therefore, when viewed from the upper edge E side of the main control board 300, since the main display 40 is not hidden by other electronic components, an unauthorized electronic component is mounted between the main display 40 and the main control board 300. There is an advantage that it is easy to confirm whether or not it is done.

Further, the main display 40 of the present embodiment is provided inside the gaming machine 1. It is assumed that the main display 40 is provided on the outside of the gaming machine 1 (for example, the front door 3) like the various effect lamps. With the above configuration, there is a possibility that the light of the main display 40 interferes with the effect by the effect lamp. In particular, in the configuration in which the display information is constantly displayed on the main display 40, the above inconvenience is likely to become apparent. In the present embodiment, since the main display 40 is provided inside the gaming machine 1, the above inconvenience is suppressed.

FIG. 7A is an example of the substrate case 600. The main control board 300 described above is housed in the board case 600. However, FIG. 7A shows the board case 600 before the main control board 300 is housed. The substrate case 600 includes an upper lid and a lower lid. In FIG. 7A, it is assumed that the substrate case 600 is viewed from the upper lid side. The substrate case 600 is provided inside the gaming machine 1 so that the upper lid can be viewed from the front when the front door 3 is opened.

As shown in FIG. 7A, each opening 602 (A to F) is formed in the substrate case 600. Each opening 602 includes an opening 602A to an opening 602F. When the main control board 300 is housed in the board case 600, the connector CNa of the main control board 300 is located inside the opening 602A in a front view. When the main control board 300 is housed in the board case 600, the connector CNb of the main control board 300 is located inside the opening 602B, the connector CNc is located inside the opening 602C, and the inside of the opening 602D when viewed from the front. The connector CNd is located at. According to the above configuration, a cable for electrically connecting the main control board 300 and other members can be attached to each connector CN while the main control board 300 is housed in the board case 600.

When the main control board 300 and the sub board 700 are housed in the board case 600, the key hole K of the sub board 700 is located inside the opening 602E in a front view. According to the above configuration, the setting key can be inserted into the keyhole K with the main control board 300 and the sub board 700 housed in the board case 600. Further, when the main control board 300 and the sub board 700 are housed in the board case 600, the setting change button 37 is located inside the opening 602F. According to the above configuration, the setting change button 37 of the sub board 700 can be operated with the main control board 300 and the sub board 700 accommodated in the board case 600.

As shown in FIG. 7A, the board case 600 is provided with a sealing mechanism 601. The sealing mechanism 601 fixes the upper lid and the lower lid of the substrate case 600. Specifically, the sealing mechanism 601 includes each sealing portion 604 (a to d) of the upper lid. Each sealing portion 604 is easily formed by breaking. One sealing portion 604 (upper lid) is fixed to the lower lid with a one-way screw that cannot be removed. For example, when the upper lid and the lower lid are fixed by the sealing portion 604a, the fixing of the upper lid and the lower lid can be released by destroying the sealing portion 604a, and then any of the other sealing portions 604 (604b to 604d). It is possible to fix the upper lid and the lower lid by using one of them. In the above configuration, the number of times the upper lid and the lower lid of the substrate case 600 can be fixed is limited to four, so that the opportunity to take out the main control substrate 300 housed in the substrate case 600 is limited. Therefore, for example, it is possible to limit the period in which a fraudulent act of modifying the main control board 300 is possible.

As shown in FIG. 7A, the seals (A to C) are attached to the upper lid of the substrate case 600. Each seal includes a seal A, a seal B, and a seal C. The sticker A displays the manufacturer name and model name of the gaming machine 1. The seal A is located near the center of the upper lid of the substrate case 600 when viewed from the front.

The seal B displays a field in which the date of use of the sealing mechanism 601 and the person in charge who used it can be entered and a management number. The management number is a number that can identify the gaming machine 1. Further, in the column of the date of use of the sealing mechanism 601, for example, the date when the sealing portion 604 (a to d) described above is destroyed is entered. Further, like the seal A, the seal B is located near the center of the upper lid of the substrate case 600. In the specific example of FIG. 7A, the seal B is located near the left side of the seal A in a front view.

The seal C has one end attached to the upper lid and the other end attached to the lower lid. Further, the seal C is formed of a member that is difficult to peel off so as not to be broken once it is attached. In the above configuration, since the seal C is broken when the upper lid and the lower lid are disassembled, it is possible to leave a trace of disassembling the upper lid and the lower lid. Further, on the sticker C, for example, the characters "opening prohibited" are displayed.

FIG. 7B is a front view of the board case 600 accommodating the main control board 300. As described above, the substrate case 600 is made of transparent resin. Therefore, each electronic component of the main control board 300 housed in the board case 600 can be visually recognized through the board case 600 (upper lid) as shown in FIG. 7B.

As shown in FIG. 7B, when the main control board 300 is housed in the board case 600, a part of the main control board 300 overlaps the seal A and the seal B in a front view. Therefore, a part of each electronic component mounted on the surface of the main control board 300 overlaps the seal A and the seal B in a front view. Electronic components that overlap the seal A and the seal B are difficult to visually recognize when the main control board 300 is housed in the board case 600.

However, depending on the electronic component, there is a case where it is required to be easily visually recognized even when the main control board 300 is housed in the board case 600. As described above, the main display 40 continuously displays each display information during the period when the power of the gaming machine 1 is ON. If the main display 40 is mounted in a region of the surface of the main control board 300 facing each seal, there is a disadvantage that the display information (game information) displayed by the main display 40 is difficult to see by each seal. obtain.

In consideration of the above circumstances, in the present embodiment, a main control board 300 (specific board) on which a main CPU 301 (game control means) for updating game information (bonus ratio, etc.) is mounted, and a transparent top cover ( The main control board 300 can be housed so that the upper cover and the front surface face each other, and a seal A and a seal B (information display sticker) for displaying specific information (such as a manufacturer name) are provided on the upper cover. The board case 600 is attached, and the main display 40 is provided which can display game information and is mounted on a region of the surface of the main control board 300 which does not face each seal. According to the above configuration, the main display 40 is mounted on the surface of the main control board 300 in a region that does not face each seal. Therefore, it is possible to suppress the inconvenience that the game information displayed by the main display 40 is difficult to see due to each sticker.

<Circuit of game machine>
The structure of the gaming machine 1 has been described above. In the following, the function of each circuit provided in the gaming machine 1 will be described with reference to FIG. As shown in FIG. 8, the gaming machine 1 includes a reel board 100, a relay board 200, a main control board 300, a sub control board 400, and a power supply board 500.

<Main control board>
As shown in FIG. 8, the main control board 300 includes a main CPU 301, a main ROM 302, a main RAM 303, a random number generator 304, and an I/F (interface) circuit 305. The main CPU 301, the main ROM 302, and the main RAM 303 may be provided as separate electronic devices, or may be provided as a one-chip microcomputer in which each element is integrally configured.

The main ROM 302 stores a control program executed by the main CPU 301 and various data (for example, a winning area lottery table) in a nonvolatile manner. The main RAM 303 stores various data used in each process executed by the main CPU 301.

The main CPU 301 reads the control program stored in the main ROM 302 and performs a predetermined process in accordance with the progress of the game, thereby performing various devices including the sub control board 400, each reel 12, the hopper 520, and the display ML. To control.

The random number generator 304 generates a random number value R1 used in an internal lottery process described later. The random number generator 304 of the present embodiment includes a counter circuit, a sampling circuit, and a pulse generation circuit (all not shown), and generates a hardware random number. Specifically, the pulse generation circuit outputs a signal to the counter circuit at a predetermined cycle. The numerical value of the counter circuit is incremented by "1" every time a signal is input from the pulse generating circuit. The sampling circuit stores the numerical value of the counter circuit as a random number value R1 when the player performs a game start operation. The random number value R1 is generated in the range of numerical values “0” to “65535”. A software random number may be adopted as the random number value R1.

In this embodiment, a random number value R2 is generated in addition to the random number value R1. The random number value R2 is a software random number acquired from a register incorporated in the main CPU 301, and is generated in the range of numerical values “0” to “255”. As described later, the random number value R2 is used in the spinner effect determination process. Further, the main CPU 301 generates a random number value R3. Like the random number value R1, the random number value R3 is a hardware random number generated in the range of numerical values “0” to “65535”. The random number value R3 is used in the AT determination process described later. A software random number may be adopted as the random number value R3.

The I/F circuit 305 inputs a signal from each switch SW (for example, the start switch 24SW) of each operation unit (for example, the start lever 24) and a signal from each sensor SE (for example, the medal sensor 34SE) to the main CPU 301. The signal from each switch SW and each sensor SE is a high level signal or a low level signal. In the present embodiment, for the sake of explanation, the signal of the first level (high level or low level) is referred to as an ON signal, and the signal of the second level (low level or high level) is referred to as an OFF signal. To do. Whether the first level, which is an ON signal, is a high level or a low level is set according to the type of the switch SW or the sensor SE.

The I/F circuit 305 outputs various signals for driving the display ML, the hopper 520, and each reel 12 to the outside of the main control board 300. Further, the I/F circuit 305 outputs various commands to the sub control board 400. The command from the sub control board 400 is not received by the main control board 300 in order to prevent an unauthorized command from being input to the main control board.

A signal from the main control board 300 is input to the reel board 100. The reel board 100 outputs a drive pulse to each reel 12 in response to a signal from the main control board 300. Each stepping motor 101 of each reel 12 is driven according to the drive pulse from the reel board 100.

The stepping motor 101 includes a plurality of (four) coils. The combination of excited coils among the coils is sequentially switched every time a drive pulse is input from the reel substrate 100, and the combinations of excited coils are sequentially switched, whereby each reel 12 is rotated. Specifically, when the combination of coils excited by the stepping motor 101 is switched once, the reel 12 rotates by a predetermined angle. For example, when the pulse is applied 24 times, the reel 12 rotates by an angle corresponding to one frame (unit area U), and when the pulse is applied 504 times, the reel 12 rotates once. In the above configuration, the shorter the time interval for applying the drive pulse, the faster the rotation speed of the reel 12.

ON/OFF signals from the plurality of reel sensors 111 (111L, 111C, 111R) are input to the main control board 300 via the reel board 100. Of the reel sensors 111, the reel sensor 111L corresponds to the reel 12L, the reel sensor 111C corresponds to the reel 12C, and the reel sensor 111R corresponds to the reel 12R. Each reel sensor 111 outputs an ON signal when the rotation angle of the corresponding reel 12 is at the reference position. On the other hand, when the rotation angle of each reel 12 is other than the reference position, each reel sensor 111 outputs an OFF signal. The main CPU 301 of the main control board 300 can determine the rotation angle of each reel 12 from the signal from each reel sensor 111 and the number of times the drive pulse is output to each stepping motor 101.

The relay board 200 relays a signal from the main control board 300 to the display ML. The display ML is driven according to the signal output from the main control board 300. In addition, the relay board 200 relays ON/OFF signals input to the main control board 300 from sensors (start switch 24SW, which will be described later) that detect an operation of each operation unit (start lever 24, etc.). Specifically, the relay board 200 relays ON/OFF signals from the 1BET switch 21SW, the MAX-BET switch 22SW, the adjustment switch 23SW, the start switch 24SW, the stop switch 25SW, and the medal sensor 34SE, as shown in FIG. To do. Further, as shown in FIG. 8, the power supply board 500 relays ON/OFF signals of various sensors or switches including the full sensor 530SE, the reset switch 512SE, and the payout sensor 112SE.

The 1BET switch 21SW detects the operation of the 1BET button 21 by the player. The ON signal from the 1BET switch 21SW is input to the I/F circuit 305 of the main control board 300 via the relay board 200. When the ON signal from the 1BET switch 21SW is input, the main CPU 301 adds one medal to the bet medal.

The MAX-BET switch 22SW detects the operation of the MAX-BET button 22 by the player. The ON signal from the MAX-BET switch 22SW is input to the I/F circuit 305 of the main control board 300 via the relay board 200. When the ON signal from the MAX-BET switch 22SW is input, the main CPU 301 sets a specified number of medals as a bet medal.

The settlement switch 23SW detects the operation of the settlement button 23 by the player. The ON signal from the settlement switch 23SW is input to the I/F circuit 305 of the main control board 300 via the relay board 200.

When the ON signal from the settlement switch 23SW is input, or when the winning symbol combination is displayed on the activated line, the main CPU 301 outputs a hopper drive signal to the hopper 520. The hopper drive signal is input from the main control board 300 to the hopper 520 via the power supply board 500. When the hopper drive signal is input, the hopper 520 pays out medals.

The payout sensor 112SE outputs a payout signal to the main control board 300 every time one medal is paid out from the hopper 520. Specifically, the payout sensor 112SE is provided at a position where a medal passing through the discharge slit 521b of the hopper 520 is detected. The payout sensor 112SE outputs a payout signal when a medal is detected. The payout signal is input to the main control board 300 via the power supply board 500. The main CPU 301 can determine the number of paid out medals by counting the number of times the payout signal is input.

The full tank sensor 530SE detects that the auxiliary storage section 530 is full. Specifically, the full tank sensor 530SE is provided at a predetermined height from the bottom of the auxiliary storage section 530, and when the number of medals inside the auxiliary storage section 530 increases and reaches the position of the full tank sensor 530SE, an ON signal is output. Is output to the main control board 300. The ON signal of full tank sensor 530SE is input to main control board 300 via power supply board 500. When the ON signal of the full sensor 530SE is input, the main CPU 301 displays, for example, a message “hopper full error” on the liquid crystal display device 30 and shifts to an error state. When the message is displayed, for example, the clerk of the game store operates the reset button 512 after collecting the medals in the auxiliary storage unit 530, and the error state is released.

The power switch 511SW is switched to an ON state or an OFF state by operating the power button 511. When the power switch 511SW is ON, power is supplied from the power supply device 510 to the gaming machine 1, and when the power switch 511SW is OFF, power from the power supply device 510 to the gaming machine 1 is cut off. Power supply device 510 generates a DC voltage when power is supplied. The DC voltage generated by the power supply device 510 is supplied to various devices including the hopper 520 via the power supply board 500.

The reset switch 512SW is provided in the power supply device 510 and outputs a reset signal to the main control board 300 when the reset button 512 is operated. The reset signal is input to the main control board 300 via the power supply board 500. Upon receiving the reset signal, the main CPU 301 initializes a predetermined storage area of the main RAM 303 and cancels, for example, an error state. Note that a plurality of reset switches 512SW (reset button 512) may be provided. For example, in addition to the reset switch 512SW provided in the power supply device 510, the lock device 4 may be provided with a reset switch. In the above configuration, for example, when the key is inserted into the keyhole of the locking device 4 and the key is rotated to the right, the front door 3 is unlocked, and when the key is rotated to the left, a reset signal is output from the reset switch. The output configuration is preferably adopted.

The setting change switch 37SW shown in FIG. 8 detects the operation of the setting change button 37. The ON signal from the setting change switch 37SW is input to the main control board 300. When the ON signal is input from the setting change switch 37SW, the main CPU 301 updates the display of the setting display unit 36. Further, when the ON signal is input from the setting change switch 37SW during the period in which the set value is not displayed on the setting display unit 36, the main CPU 301 causes the stored number display 16 to display the regulation period ratio (described later).

The medal sensor 34SE detects medals inserted from the medal insertion unit 8. Specifically, the medal sensor 34SE outputs an ON signal when the medal is located inside the selector 34 in the medal flow path. On the other hand, the medal sensor 34SE outputs an OFF signal when the medal is not located inside the selector 34. The ON/OFF signal from the medal sensor 34SE is input to the main control board 300 via the relay board 200. In addition to the medal sensor 34SE of the selector 34 described above, a medal sensor may be provided on the inserted medal guide member 522 located downstream of the selector 34. In the above configuration, when the ON signal of the medal sensor of the insertion medal guide member 522 is input after the ON signal of the medal sensor 34SE of the selector 34 is input, the main CPU 301 determines that a medal has been inserted. Good. On the other hand, for example, if the ON signal of the medal sensor 34SE of the selector 34 is not input after the ON signal of the medal sensor 34SE of the selector 34 is input, it is possible that medals are accumulated in the medal flow path. Therefore, the main CPU 301 may notify the error.

ON/OFF signals from the plurality of stop switches 25SW (25SWL, 25SWC, 25SWR) are input to the main control board 300 via the relay board 200. Of the stop switches 25SW, the stop switch 25SWL corresponds to the stop button 25L, the stop switch 25SWC corresponds to the stop button 25C, and the stop switch 25SWR corresponds to the stop button 25R. The main CPU 301 controls the stop of the reel 12 corresponding to the stop switch 25SW to which the ON signal is input. Specifically, when an ON signal is input from the stop switch 25SWL, the stop control of the reel 12L is performed. Similarly, the main CPU 301 performs stop control of the reel 12C when an ON signal is input from the stop switch 25SWC, and controls stop of the reel 12R when an ON signal is input from the stop switch 25SWR.

The start switch 24SW detects the operation of the start lever 24 by the player. The ON signal from the start switch 24SW is input to the I/F circuit 305 of the main control board 300 via the relay board 200. When the ON signal from the start switch 24SW is input, the main CPU 301 controls each stepping motor 101 to rotate each reel 12, for example. Further, the ON signal from the setting change switch 37SW is input to the main control board 300.

The start switch 24SW of this embodiment is formed so as to detect the direction in which the start lever 24 is operated. Specifically, the start switch 24SW can individually detect any one of a push-up operation of pushing up the start lever 24, a push-down operation of pushing down, a right operation of tilting to the right side, and a left side operation of tilting to the left side when viewed from the player side. is there. For example, the start switch 24SW includes a start switch 24SWU that outputs an ON signal when the start lever 24 is pushed up, a start switch 24SWD that outputs an ON signal when the start lever 24 is pushed, and an ON switch when the right lever is operated. It is composed of a plurality of sensors including a start switch 24SWR for outputting a signal and a start switch 24SWL for outputting an ON signal when operated leftward. According to the above configuration, for example, the effect to be executed can be made different depending on whether the start lever 24 is pushed down or pushed up.

<Sub control board>
The sub-control board 400 controls the liquid crystal display device 30, the speakers (31, 32), and each lamp (for example, the effect lamp 28). As shown in FIG. 8, the sub control board 400 is composed of a plurality of boards including an effect control board 410, an image control board 420, and a sound board 430. Further, the sub-control board 400 includes various sensors including an effect button switch 26SW and a direction designating switch 27SW, a housing lamp 5, an effect lamp 28, a stop operation sequence display lamp 29, a lever effect lamp 42, and an upper portion. Various lamps including the lamp 35 are electrically connected.

Further, as shown in FIG. 8, the volume control switch 44 is electrically connected to the sub control board 400. The volume adjustment switch 44 is used to adjust the master volume of the gaming machine 1. As the volume adjusting switch 44, for example, a dip switch is preferably adopted. As described above, the master volume can also be adjusted by operating the direction designating button 27. That is, the master volume is adjusted by operating either the direction specifying button 27 or the volume adjusting switch 44.

In the present embodiment, the adjustable master volume differs depending on whether the direction designation button 27 is operated or the volume adjustment switch 44 is operated. Specifically, when the direction designation button 27 is operated, the master volume can be adjusted to any of the numerical value “1” to the numerical value “5” (five steps). On the other hand, when the volume adjustment switch 44 is operated, the master volume can be adjusted to any one of the numerical value "1", the numerical value "3" and the numerical value "5" (three levels). The adjustable master volume may be the same when the direction designation button 27 is operated and when the volume adjustment switch 44 is operated.

As shown in FIG. 8, the effect control board 410 includes an I/F circuit 411, a sub CPU 412, a sub ROM 413, and a sub RAM 414. The effect control board 410 (sub CPU 412) controls various lamps including the housing lamp 5, the effect lamp 28, the stop operation sequence display lamp 29, and the lever effect lamp 42, and the sound board 430. In addition, the production control board 410 gives the image control board 420 a command for displaying each image on the liquid crystal display device 30.

The sub ROM 413 stores a control program executed by the sub CPU 412 and various data. For example, an effect lottery table for determining the type of effect and lamp data indicating a blinking pattern of various lamps are stored in the sub ROM 413.

The sub RAM 414 functions as a work area that stores various data in a volatile manner. The I/F circuit 411 receives a command from the main control board 300 (I/F circuit 305). The command received by the I/F circuit 411 is supplied to the sub CPU 412. The command received by the I/F circuit 411 is, for example, a display winning combination command indicating the type of winning combination stopped on the activated line.

The sub CPU 412 executes a control program stored in the sub ROM 413, and controls various lamps (for example, the housing lamp 5) and the sound board 430 based on each data stored in the sub ROM 413. For example, the sub CPU 412 reads the data indicating the blinking pattern of the housing lamp 5 from the sub ROM 413 and causes the housing lamp 5 to blink. In addition, the sub CPU 412 generates a random number value R4 used in an effect control process described later. As the random number value R4, for example, a random number in the range of 0 to 65535 is preferably adopted. The sub ROM 413 may be composed of a single electronic component or a plurality of electronic components (storage devices).

The image control board 420 causes the liquid crystal display device 30 to display various images according to commands from the effect control board 410. As shown in FIG. 8, the image control board 420 includes an image control CPU 421, an image control ROM 422, a VDP (Video Display Processor) 423, a CGROM 424, and a VRAM 425.

The image control CPU 421 executes the control program stored in the image control ROM 422, and gives the VDP 423 an instruction corresponding to the command from the effect control board 410. The CGROM 424 stores compression-encoded image data (for example, texture data). The VDP 423 is configured to include an image decoder and a drawing circuit (both not shown). When the instruction from the image control CPU 421 is input to the VDP 423, the image decoder reads the image data from the CGROM 424 according to the instruction. The image decoder expands (decodes) the read image data and stores it in the RAM 425. The drawing circuit causes the liquid crystal display device 30 to display various images according to the image data stored in the RAM 425. The RAM 425 also stores various data generated by each process of the image control CPU 421. The RAM 425 is provided with a command storage area for storing a sound control command transmitted to the sound source IC 431.

The sound board 430 is controlled by the image control CPU 421 to generate an acoustic signal. The acoustic signal generated by the sound board 430 is supplied to the speaker 31 and the speaker 32 and is output as a sound wave. As shown in FIG. 8, the sound board 430 includes a sound source IC 431 and a sound source ROM 432. The image control CPU 421 controls the sound board 430 (sound source IC 431) according to a command from the sub CPU 412.

The sound source ROM 432 compresses and stores a plurality of acoustic data. Each sound data is, for example, data indicating each music in a specific game state, a sound output each time the player operates the stop button 25, and each sound including an error sound output in an error state.

The sound source IC 431 generates an acoustic signal from the acoustic data of the sound source ROM 432. Further, the tone generator IC 431 is configured to include a decoder, a control register, and an A/D converter (none of which are shown). The decoder of the sound source IC 431 reads out acoustic data from the sound source ROM 432 according to an instruction from the sub CPU 412. Further, the decoder of the sound source IC 431 stores the sound data in the control register after adjusting the volume of the read sound data. A plurality of acoustic data are stored in the control register, and each acoustic data stored in the control register is supplied to the A/D converter in the order in which they are stored. The A/D converter generates an acoustic signal from the acoustic data and supplies it to the amplifier 433. The amplifier 433 amplifies the acoustic signal supplied from the sound source IC 431 (A/D converter) and supplies it to the speaker 31 and the speaker 32. A CPU for controlling the sound source IC 431 may be provided separately from the sub CPU 412 and the image control CPU 421.

<Data used by main CPU>
The respective circuits of the gaming machine 1 have been described above. Hereinafter, various data stored in the main ROM 302 will be described with reference to the drawings. In the main ROM 302, the symbol code table shown in FIG. 9, the winning area lottery table shown in FIG. 10, the winning combination determination table shown in FIG. 11, the winning combination defining table shown in FIG. 12, the transition symbol defining table shown in FIG. The instruction determination table shown in FIG. 17 and the rotating body effect determination table shown in FIG. 19 are stored.

FIG. 9 is a conceptual diagram of the symbol code table. The symbol code table is configured to include a symbol code that identifies each symbol on each reel 12. As can be seen from FIG. 9, each reel 12 has “red seven”, “black BAR”, “white BAR”, “replay x”, “replay y”, “bell”, “star bell”, “plum”, “watermelon”, “cherry”. 10 types of patterns are arranged. As shown in FIG. 9, each symbol code corresponds to each symbol. Specifically, "red seven" corresponds to the symbol code 01 "00000001", "black BAR" corresponds to the symbol code 02 "00000010", and "white BAR" corresponds to the symbol code 03 " "00000011" corresponds, "Replay x" corresponds to the symbol code 04 "00000100", "Replay y" corresponds to the symbol code 05 "00000101", and "Bell" corresponds to the symbol code 06 " "0000110" corresponds, "Star Bell" corresponds to the symbol code "0000111" of the symbol code, "Plum" corresponds to the symbol code 08 of "00001000", and the "watermelon" symbol code 09 corresponds to "00001001", and "cherry" corresponds to the symbol code "000010010". The symbol code is used, for example, in a priority order storing process described later.

FIG. 10 is a conceptual diagram of a winning area lottery table. The main CPU 301 determines the winning area by using the winning area lottery table and the random number value R1 in the internal lottery process described later. As shown in FIG. 10, each winning area lottery table is configured to include a plurality of winning areas and each lottery value corresponding to each winning area. FIG. 10 shows the names of the winning areas. The winning area lottery table is stored in the main ROM 302 for each set value (1 to 6). FIG. 10 illustrates a winning area lottery table that is referred to when the setting value is “1”.

Each winning area of the winning area lottery table specifies each winning combination defined in the winning combination determination table shown in FIG. In addition, in FIG. 11, there is a portion in which replay is abbreviated as “lip”. Similarly, in other figures, replay may be abbreviated as “rep”.

For example, it is assumed that the "batter order replay X1" of the winning area number "01" is determined by the internal lottery process. As shown in FIG. 11, the winning area number “01” specifies the winning combination “normal replay” and the winning combination “RT2 transition replay”. That is, in the game in which the winning area "Batting Order Replay X1" is won, a plurality of types of winning combinations are designated in duplicate.

Each lottery value in the winning area lottery table is subtracted from the random number value R1 in the internal lottery process. Specifically, in the internal lottery process, the main CPU 301 subtracts each lottery value corresponding to each winning area from the random number value R1 in the ascending order of the winning area (the order of “00” to “32”). In the internal lottery process, the winning area in which the result of subtracting the lottery value from the random number value R1 is a negative number is determined. Since the larger the lottery value is, the higher the probability of becoming a negative number when subtracted from the random number value R1 is, the larger the lottery value in the winning area is, the higher the probability of winning is.

As shown in FIG. 10, the winning area lottery table is configured to include each lottery value for each RT state. Each RT state includes an RT0 state, an RT1 state, an RT2 state and an RT3 state. Each RT state shifts when an RT shift pattern described later is stopped and displayed on the activated line. The main CPU 301 subtracts the random number value R1 corresponding to the RT state from the random number value R1. Therefore, the probability of winning each winning area depends on the RT state.

As shown in FIG. 10, the winning area lottery table includes each lottery value in the RB state. The RB state is shifted to when the symbol combination “black BAR-black BAR-black BAR” related to the RB combination is stopped and displayed on the activated line. The prescribed number of bet medals in the RB state is three. The RB state ends when the winning winning combination (bell combination) is stopped and displayed on the activated line eight times.

When the symbol combination "red seven-red seven-red seven" related to the BB combination is stopped and displayed on the activated line, the state shifts to the BB state. In the BB state, it is possible to continuously shift to the RB state. Specifically, when the BB state is started, the first RB state is entered. The RB state ends when the winning combination is stopped and displayed eight times, like the RB state started when the symbol combination of the RB combination is stopped and displayed. When the first RB state has ended and the BB state has not ended, the state immediately shifts to the second RB state. Then, until the BB state ends, the next RB state starts immediately after the RB state ends. The BB state ends when 297 medals are paid out. If the RB state continues in the game in which the BB state has ended, the RB state ends in the game (at the same time as the BB state). With the above configuration, each game in the BB state becomes the RB state.

In the present embodiment, the BB state and the RB state are collectively referred to as "bonus operating state". The BB combination and the RB combination are collectively referred to as a "bonus combination". When the bonus operation state ends, the main CPU 301 shifts to the RT0 state. Further, as shown in FIG. 10, the winning area lottery table includes each lottery value in the inside state. When the bonus combination is not stopped and displayed on the activated line in the game in which the bonus combination is won, the main CPU 301 shifts to the internal state where the state in which the bonus combination is won is maintained. As understood from FIG. 10, each lottery value of the winning area numbers “01” to “11” (hereinafter, referred to as “re-game winning area”) is different for each RT state.

FIG. 12 is a conceptual diagram of the winning combination specifying table. The winning combination regulation table defines combinations of symbols that are permitted to be stopped on the activated line in the game won by each winning combination. For example, in the game in which the winning combination “BB combination” has been won, it is permitted that the symbol combination “red seven-red seven-red seven” is stopped on the activated line. Further, for example, in the game in which the winning combination “correct answer bell” is won, each symbol combination of “bell-bell-bell” and “star bell-bell-bell” can be stopped on the activated line.

As shown in FIG. 12, the winning combination regulation table is configured to include the permission bit numbers of each winning combination and the number of medals to be paid out when the symbol combination related to each winning combination is stopped on the activated line. FIG. 12 shows the payout number when the symbol combination related to each winning combination is stopped on the activated line in the game state in which the specified number is 3. In addition, when a plurality of winning combinations are won in succession, the winning combination having the larger number of payouts is preferentially displayed on the activated line. Further, the replay is stopped and displayed on the activated line in preference to other winning combinations, and the bonus winning combination has a lower priority than the other winning combinations.

As shown in FIG. 12, the winning combination “upper bells 1 to 8”, “correct answer bell”, “watermelon role”, “corner cherry role”, “middle cherry role”, “one piece role A” or “one piece role B” (winning prize) When the symbol combination related to the winning combination designated by the area winning game) is displayed on the activated line, the payout number of medals corresponding to each winning combination is given to the player. In the present embodiment, the winning combination to which the medals are paid out when displayed on the activated line is referred to as “winning winning combination”. In addition, when "normal replay", "RT2 transition replay", and "RT3 transition replay" (winning combination designated in the game in which the re-game winning area is won) is displayed on the activated line, the next game is set as the re-play. It In this embodiment, a winning combination whose next game is a re-game when displayed on the activated line may be collectively referred to as "replay".

Each permission bit number in the winning combination regulation table specifies each display permission bit in the display permission bit storage area of the main RAM 303. The display permission bit storage area is configured to include a plurality of display permission bits, and each display permission bit corresponds to each winning combination. For example, it is assumed that the batting order replay X1 of the winning area number “01” is won and each symbol combination of the winning combination “normal replay” and “RT2 transition replay” is permitted to stop on the activated line. In the above case, the display permission bits designated by the permission bit numbers “7” and “2” in the display permission bit storage area are set to “1”, and the others are set to “0”.

The main RAM 303 stores a display combination storing area that is compared with the display permission bit storing area in the display determination processing described later. The display combination storage area is configured to include a plurality of displayable bits, and each displayable bit corresponds to each winning combination (similar to the display permission bit storage area). Further, each displayable bit is set to "1" when the symbol combination relating to the winning combination corresponding to the displayable bit may stop on the activated line, and the symbol combination relating to the corresponding winning combination is valid. Set to "0" if the line has no chance of stopping. For example, at the time when each reel 12 starts to rotate, all of the displayable bits are set to "1" because the symbol combinations related to all winning combinations may stop on the activated line. Further, each displayable bit in the display combination storing area is updated every time each reel 12 is stopped, and at the time when all reels 12 are stopped, it corresponds to the symbol combination related to the winning combination which is actually stopped on the activated line. Only the displayable bit becomes "1".

The winning combination won in the internal lottery process is stopped on the activated line according to the operation mode of each stop button 25 by the player. Specifically, each winning combination stops on the activated line in accordance with the stop operation position of each stop button 25 and the order of the stop operation. For example, a symbol located within a range of four frames (five frames including the stop operation position) from the stop operation position (hereinafter referred to as a "drawing range") can be stopped on the effective line, and a pattern located outside the drawing range is , Even the symbols that make up the winning combination are not stopped on the activated line (so-called "missing" occurs). Further, as described above, in one game, a plurality of types of winning combinations may be won in duplicate. In a game in which a plurality of types of winning combinations have been won, for example, the symbol combination related to the winning combinations according to the order of the stop operation is stopped on the activated line.

FIG. 13 and FIG. 14 are explanatory diagrams of the correspondence relationship between the winning area, the stop operation sequence, and the winning combination that stops on the activated line (the combination of symbols stopped on the activated line).

FIG. 13 is a diagram illustrating a winning combination (replay) that stops on the activated line in each stop operation sequence in the game in which the re-game winning area is won. As shown in FIG. 13, when any of the hit areas “Batting order replays X1 to X6” is won, “normal replay” or “RT2 transition replay” is stopped on the activated line according to the mode of the stop operation. Specifically, in the game in which the winning area "Batting Order Replay X1" has been won, the reel 12L has a first stop operation, the reel 12C has a second stop operation, and the reel 12R has a third stop operation. In the case of the “left middle right” stop operation order), the symbol combination related to the winning combination “RT2 transition replay” is stopped and displayed on the activated line. On the other hand, in the game in which the winning area “Batting Order Replay X1” has been won, when the stop operation is performed in an order other than “left middle right”, the symbol combination related to the winning combination “normal replay” is stopped and displayed on the activated line.

As shown in FIG. 13, in the game in which the winning area "Batting Order Replay X2" has been won, when the stop operation is performed in the order of "left and right middle", the symbol combination related to the winning combination "RT2 transition replay" is stopped and displayed on the activated line. It On the other hand, in the game in which the winning area “Batting Order Replay X2” has been won, when the stop operation is performed in an order other than “right and left middle”, the symbol combination related to the winning combination “normal replay” is stopped and displayed on the activated line. Further, in the game in which the winning area "Batting order replay X3" is won, when the stop operation is performed in the order of "middle left and right", the symbol combination related to the winning combination "RT2 transition replay" is stopped and displayed on the activated line. On the other hand, in the game in which the winning area “Batting Order Replay X3” has been won, when the stop operation is performed in an order other than “middle left/right”, the symbol combination related to the winning combination “normal replay” is stopped and displayed on the activated line. Similarly, in the game in which the winning area “Batting Order Replay X4” has been won, when the stop operation is performed in the order of “middle right left”, the symbol combination related to the winning combination “RT2 transition replay” is stopped and displayed on the activated line. On the other hand, in the game in which the winning area “Batting Order Replay X4” has been won, when the stop operation is performed in an order other than “middle right left”, the symbol combination related to the winning combination “normal replay” is stopped and displayed on the activated line. In the game in which the winning area "Batting Order Replay X5" has been won, when the stop operation is performed in the order of "Right Left Middle", the symbol combination related to the winning combination "RT2 Transition Replay" is stopped and displayed on the activated line, except "Right Left Middle". When the stop operation is performed in order, the symbol combination related to the winning combination “normal replay” is stopped and displayed on the activated line. In the game in which the winning area "Batting Order Replay X6" has been won, when the stop operation is performed in the order of "Right Middle Left", the symbol combination related to the winning combination "RT2 Transition Replay" is displayed stopped on the activated line, and "Right Middle Left" When the stop operation is performed in the order other than, the symbol combination related to the winning combination “normal replay” is stopped and displayed on the activated line.

As shown in FIG. 13, in the game in which the winning area “Batting Order Replay Y1” has been won, when the stop operation is performed at the first left stop, the symbol combination related to the winning combination “RT3 transition replay” is stopped and displayed on the activated line. On the other hand, in the game in which the winning area “Batting Order Replay Y1” has been won, when the stop operation is performed other than the left first stop, the symbol combination related to the winning combination “normal replay” is stopped and displayed on the activated line. In the game in which the winning area "Batting Order Replay Y2" has been won, when the stop operation is performed at the first stop in the middle, the symbol combination related to the winning combination "RT3 transition replay" is stopped and displayed on the activated line. On the other hand, in the game in which the winning area "Batting Order Replay Y2" is won, when the stop operation is performed other than the middle first stop, the symbol combination related to the winning combination "normal replay" is stopped and displayed on the activated line. In the game in which the winning area "Batting Order Replay Y3" has been won, when the stop operation is performed at the first stop on the right, the symbol combination related to the winning combination "RT3 transition replay" is stopped and displayed on the activated line. On the other hand, in the game in which the winning area "Batting Order Replay Y3" has been won, when the stop operation is performed other than the right first stop, the symbol combination related to the winning combination "normal replay" is stopped and displayed on the activated line.

As shown in FIG. 13, in the game in which the winning area “BAR replay” is won, when the stop operation is performed at the first stop on the right, the symbol combination of the winning combination “normal replay” or the winning combination “BAR replay” is stopped in the activated line. Is displayed. Specifically, in the case where the winning area "BAR Replay" is the first stop operation in the winning game and each reel 12 is stopped in the pulling range of the white BAR symbol, the winning combination "BAR Replay" Will be stopped on the active line. On the other hand, when any of the reels 12 is stopped outside the pulling range of the white BAR symbol, the winning combination "normal replay" is stopped and displayed. In the game in which the winning area "normal replay" is won, the symbol combination of the winning combination "normal replay" is stopped and displayed on the activated line regardless of the stop operation mode.

FIG. 14 is a diagram for explaining a winning combination in which the winning area "Batting Order Bell" (L1 to L4, C1 to C4, R1 to R4) wins in the winning line in each stop operation order in the game. When the winning area “Batting Order Bell” is determined, one of the winning combinations “upper bells 1 to 8” and the winning combination “correct answer bell” are duplicated. As can be understood from FIG. 14, in the game in which the batting order bell is won, the symbol combination related to the upper stage bell or the correct answer bell stops on the activated line according to the stop operation order. In this embodiment, the stop operation sequence in which the symbol combination related to the correct answer bell is stopped and displayed on the activated line is referred to as the “correct answer pressing order” of the correct answer bell.

As shown in FIG. 14, in the game in which the batting order bell L (1 to 4) is won, when the stop operation is performed by the left first stop (correct answer pressing order), the correct answer bell is stopped and displayed on the activated line. On the other hand, in the game in which the batting order bell L is determined, when the stop operation is performed in an order other than the left first stop, the stop control is performed in which the upper stage bell won in the current game is drawn into the activated line. The upper bell may be dropped depending on the stop operation position. When the upper bell is missed, the RT1 transition pattern (missed eye) is stopped and displayed on the activated line.

As shown in FIG. 14, in the game in which the batting order bell C (1 to 4) is won, when the stop operation is performed at the first stop in the middle (correct answer pressing order), the correct answer bell is stopped and displayed on the activated line. On the other hand, in the game in which the batting order bell C is determined, when the stop operation is performed in an order other than the middle first stop, the stop control is performed in which the upper stage bell won in the current game is drawn into the activated line. Further, as shown in FIG. 14, in the game in which the batting order bell R (1 to 4) is won, when the stop operation is performed at the first stop on the right (correct answer pressing order), the correct answer bell is stopped and displayed on the activated line. On the other hand, in the game in which the batting order bell R is determined, when the stop operation is performed in an order other than the right first stop, the stop control for pulling the upper stage bell won in the current game into the activated line is performed.

As can be understood from the above explanation, in the game in which the winning area "bat order bell" is won, when the stop operation is performed in the correct answer pressing order, the symbol combination related to "correct answer bell" (the number of payouts is 9) is effective. Stop on the line. On the other hand, if the stop operation is performed in a sequence other than the correct pressing order, the loose eye may stop on the effective line. Therefore, when the game is played in the correct answer pressing order, it is advantageous to the player as compared with the case where the game is played in the order other than the correct answer pressing order. As will be described in detail later, when the main CPU 301 is in the AT state, the correct answer pressing order of the correct answer bell is notified.

As described above, the RT state includes the RT0 state to the RT3 state. Further, the RT state shifts when the RT shift symbol is displayed on the activated line. Specifically, when the RT1 shift symbol is displayed on the activated line, the RT1 state is shifted. Similarly, when the RT2 transition symbol is displayed on the activated line, the state is shifted to the RT2 state, and when the RT3 transition symbol is displayed on the activated line, the state is shifted to the RT3 state.

FIG. 15 is a conceptual diagram of the RT transition symbol regulation table. As understood from FIG. 15, the RT2 transition symbol is a symbol combination of RT2 transition replay. That is, when the symbol combination related to the RT2 transition replay is stopped and displayed on the activated line, the right to replay is granted, and the state shifts to the RT2 state. Further, the RT3 transition symbol is a symbol combination of RT3 transition replay. That is, when the symbol combination related to the RT3 transition replay is stopped and displayed on the activated line, the right to replay is granted and the state shifts to the RT3 state.

The RT1 transition pattern includes a specific lost eye. The lost eye of the RT1 transition pattern is stopped and displayed in the activated line when each bell combination (correct answer bell, upper bell) is missed in the game in which the winning area "bat order bell" is won. That is, when the stop operation is performed in a sequence other than the correct pressing order of the batting order bell, and the stop operation is performed at a timing when the selected upper bell cannot be pulled in, the RT1 transition symbol is stopped and displayed on the activated line.

As will be described in detail later, when the main CPU 301 is in the AT state, the stop operation sequence in which the RT2 transition replay is stopped and displayed and the stop operation sequence in which the RT3 transition replay is stopped and displayed are informed. Further, when the main CPU 301 is in the AT state, by notifying the correct pressing order of the batting order bell, the symbol combination relating to the correct answer bell can be stopped and displayed, and the RT1 transition symbol (missed eye) is prevented from being stopped and displayed. be able to.

The main CPU 301 controls the instruction indicator 16 according to each gaming state including the AT state, the normal state, the chance state, the start preparation state, the precursor state, the internal state, the bonus operation state and the end preparation state. A game state flag indicating the current game state is stored in the main RAM 303. In each game, the main CPU 301 transmits a game state command indicating a game state flag to the sub CPU 412. The sub CPU 412 determines an effect according to the game state indicated by the game state command.

In each game in the AT state, the main CPU 301 causes the instruction display device 16 to display instruction information for instructing the stop operation order. In the present embodiment, the main CPU 301 causes the instruction display device 16 to display instruction information for instructing a stop operation sequence advantageous to the player in the AT state. On the other hand, in the normal state, the instruction of the stop operation sequence advantageous to the player is not given. Therefore, the AT state is a gaming state that is more advantageous to the player than the normal state. Compared to the normal state, the chance state makes it easier to determine the transition to the AT state, and is a gaming state advantageous to the player.

In the start preparation state, similarly to the AT state, a stop operation sequence advantageous to the player is instructed. In the present embodiment, a period during which a stop operation mode advantageous to the player is instructed is referred to as "instruction period". The instruction period is each game state including the start preparation state and the AT state. Further, a period (normal state or the like) other than the instruction period may be referred to as a “non-instruction period”. It should be noted that a part of the game in the chance state becomes the instruction period, and in the chance state, the player is instructed on a stop operation mode that is advantageous. Specifically, the instruction period is the period from the transition to the chance state until the first batting order bell or batting order replay is won. With the above configuration, the instruction information is displayed at least once in the chance state, and it is possible to let the player recognize that the regulation period has been entered.

FIG. 16 is a diagram for explaining the transition of the game state. As shown in FIG. 16, the game state shifts at a specific trigger. For example, in the normal state, if the AT state is won, the state may shift to the precursor state. Specifically, in each game, the main CPU 301 determines whether or not the AT state is true by AT determination processing. When winning the AT state in the normal state, the main CPU 301 changes the above-mentioned gaming state flag from the normal state to the omen state. Further, when the main CPU 301 wins the AT state in the normal state, the main CPU 301 sets an initial value in the precursor counter.

The omen counter indicates the number of games played from the omen state to the AT state, and is provided in the main RAM 303, for example. As the initial value of the precursor counter, any of the numerical values “0” to “32” is determined by lottery. The main CPU 301 subtracts the numerical value "1" from the predictive counter in each game in the predictive state, and when the predictive counter is subtracted to the numerical value "0", shifts the game state to the start preparation state. When the AT state is won in the normal state, the main CPU 301 stores the initial value “50” in the AT counter indicating the number of remaining games in the AT state. The AT counter is provided in the main RAM 303, for example.

In the above configuration, when the initial value of the precursor counter is a numerical value “1” to “32”, the state shifts to the AT state through the precursor state of the game once to 32 times. On the other hand, when the initial value of the precursor counter is a numerical value “0”, the next game won in the AT state is in the start preparation state. Even when the AT state is not won, the configuration may be such that the state shifts to the precursory state of Gase at a specific trigger (for example, winning of a rare role).

As shown in FIG. 16, when the precursory state is completed, the state shifts to the AT state via the start preparation state. In the start preparation state, the main CPU 301 causes the instruction display device 16 to display the instruction information for instructing the correct answer pressing order of the RT2 transition replay and the instruction information for instructing the correct answer pressing order of the RT3 transition replay. In the above configuration, when the stop operation is performed in the order instructed by the instruction information in the start preparation state, the RT2 transition replay is stopped and displayed on the activated line, the RT state transitions to the RT2 state, and then the RT3 transition replay. Is stopped and displayed on the activated line, and the RT state shifts to the RT3 state.

Further, in the start preparation state, the main CPU 301 causes the instruction display device 16 to display instruction information for instructing the correct answer pressing order of the correct answer bell. In the above configuration, when the stop operation is performed in the order instructed by the instruction information, the RT1 transition symbol is not stopped and displayed on the activated line (the correct answer bell is not missed), so the RT2 state is shifted to the RT1 state (fall) do not do. When the RT state shifts to the RT3 state, the main CPU 301 shifts the game state from the start preparation state to the AT state. The AT counter indicating the number of remaining games in the AT state is not decremented in the start preparation state.

In the AT state, as in the start preparation state, the main CPU 301 instructs the correct answer pressing order of the correct answer bell, the instruction information indicating the correct pressing order of the RT2 shift replay, and the correct pressing order of the RT3 shift replay. The instruction information and the instruction display 16 are displayed. Further, the main CPU 301 subtracts the numerical value “1” from the AT counter in each game in the AT state. The AT state is, in principle, the RT3 state. Therefore, since the batting order replay X is not won, the correct pressing order of the RT3 transition replay is not designated in the AT state. However, for example, in the game in the AT state in which the batting order bell is won, if the stop operation is performed in a sequence other than the instructed order (when an operation error is made), the RT1 transition symbol stops on the effective line, and the RT3 state to the RT1 state May move to. Even in the above case, since the correct pressing order of the RT3 transition replay and the RT2 transition replay is instructed in the AT state, the RT1 state can be returned to the RT3 state by following the instruction of the instruction information.

When the AT counter indicating the number of remaining games in the AT state is subtracted to the numerical value “0”, the main CPU 301 shifts the game state from the AT state to the end preparation state. In each game in the AT state, the value of the AT counter may be added due to a specific trigger (winning of a rare role) or the like. That is, the number of remaining games in the AT state may be added. In the end preparation state, when the RT1 transition symbol is stopped and displayed (when the batting order bell is missed), the state transitions to the normal state.

A chance state determination process is executed in each game in the normal state. In the chance state determination process, whether or not to grant the right to shift to the chance state (whether to shift to the chance state) is determined by lottery. Further, in the chance state determination processing, the right to shift to the chance state plural times may be given. When the right to shift to the chance state is granted a plurality of times, even if the shift to the AT state is not decided in the present chance state, the state then shifts to the next chance state. Therefore, when the right to shift to the chance state is given multiple times, the shift to the AT state is easier to be decided than when the right to shift to the chance state is given once. When it is decided to shift to the chance state, as in the case of shifting to the AT state, there are a case of shifting to the chance state through the precursory state and a case of shifting to the chance state without passing through the predictive state.

In each of the games in the chance state, the transition to the AT state is determined with a higher probability than in each of the games in the normal state. The chance state ends under a predetermined end condition. Specifically, the chance state ends with 10 games. When the transition to the AT state is determined in the chance state, the state is subsequently shifted to the AT state. On the other hand, in 10 games in the chance state, if the transition to the AT state is not decided, then it shifts to the normal state.

As described above, in the normal state, when the right to shift to the AT state is given and the right to shift to the chance state is given, it is possible to shift to each gaming state (AT state, chance state) in which the gaming state is advantageous become. In the present embodiment, the period from the grant of the right to shift to each advantageous gaming state to the end of the advantageous gaming state is referred to as a "regulation period". Specifically, the precursory state and the start preparation state, which are interposed between the normal state and the AT state, are included in the regulation period, like the AT state and the chance state. Further, the precursory state interposed between the normal state and the chance state is included in the regulation period.

As described above, each game state of the main CPU 301 includes the inside state and the bonus operation state. When the bonus combination is won, the state shifts to the inside state, and in the inside state, the state where the bonus combination is won is maintained. In the internal state, when the symbol combination related to the bonus combination is stopped and displayed on the activated line, the bonus operation state is entered. Specifically, the bonus operation state includes an RB state and a BB state, and shifts to the RB state when the symbol combination of the RB combination is stopped and displayed, and BB when the symbol combination of the BB combination is stopped and displayed. Transition to the state.

The internal state and the bonus operation state may be included in the regulation period or may not be included in the regulation period depending on the gaming state in which the bonus combination is won. Specifically, when the bonus combination is won in the omen state, the start preparation state, the chance state or the AT state, the internal state and the bonus operation state thereafter are included in the restriction period. On the other hand, when the bonus combination is won in the normal state or the preparation state for ending, the internal state and the bonus operation state thereafter are not included in the regulation period. That is, the internal middle state and bonus operation state after the bonus combination is won during the regulation period are included in the regulation period, and the internal middle state and bonus operation state after the bonus role is won outside the regulation period are included in the regulation period. Absent. However, the regulation period may end in the middle of the bonus operation state that has shifted from the regulation period.

In this embodiment, the number of games played during the restricted period is controlled to be equal to or less than a predetermined number of games. Specifically, the number of games played during the restricted period is 1500 times or less. As described above, the number of remaining games in the AT state may be added. In the present embodiment, the addition of the number of remaining games in the AT state is determined so that the number of games in the restriction period is 1500 times or less. The number of games played during the regulation period is stored in the regulation counter. The regulation counter is provided in the main RAM 303, for example, and is added in each game during the regulation period.

When the bonus operation state is completed, the state is changed (returned) to the game state in the game in which the bonus combination is won. For example, when the bonus combination is won in the normal state, the state is shifted to the normal state after the bonus operation state is finished. In addition, when the bonus role is won in the chance state, it shifts to the chance state after the bonus operation state ends, and when the bonus role is won in the omen state, it shifts to the omen state after the bonus operation state ends and in the start preparation state. When the bonus combination is won, the state shifts to the start preparation state after the bonus operation state ends. However, when the bonus combination is won in the AT state, the start preparation state is entered after the bonus operation state is completed. In addition, when the bonus combination is won in the end preparation state, the state shifts to the normal state after the bonus operation state ends. However, in the bonus operation state, even when the number of games after the right to shift to the AT state is reached reaches a predetermined number of times (1500 times), even if the bonus combination is won in the AT state , After the bonus operation state ends, the state shifts to the normal state.

The regulation counter is initialized under various conditions. For example, the regulation counter is initialized when the AT state ends. Further, in the case where the bonus operation state is entered in the regulation period (AT state), and when the number of games in the regulation period reaches 1500 times in the ongoing bonus operation state, the regulation period ends in the bonus operation state. , The regulation counter is initialized.

Further, when the chance state ends and the AT state is not transitioned (when the AT state is not won in the chance state), the regulation counter is initialized. However, if the right to shift to the chance state is given multiple times, the regulation counter may not be initialized even if the chance state ends. Specifically, when the present chance state has ended and the right to transition to the next chance state has already been granted (the right to transition to the current chance state and the right to transition to the next chance state). If (and are added at once), the regulation counter is not initialized when the present chance state ends.

FIG. 17 is a conceptual diagram of each instruction determination table (A, B). In each game, the main CPU 301 determines an instruction number from the instruction determination table and displays instruction information (“1” to “9”) corresponding to the instruction number on the instruction display device 16. Further, the main CPU 301 transmits a command (a second command described later) indicating the instruction number determined in each game to the sub control board 400 (sub CPU 412).

Each instruction determination table includes an instruction determination table A (FIG. 17A) and an instruction determination table B (FIG. 17B). The instruction determination table A is used to determine the instruction number of each game in the non-instruction period (normal state or the like). The instruction determination table B is used to determine the instruction number of each game in the instruction period (AT state or the like). Further, as shown in FIG. 17, each instruction determination table is configured to include each instruction number for each winning area.

As shown in FIG. 17A, the instruction number "99" is determined regardless of which winning area is won in the non-instruction period. When the instruction number “99” is determined, the instruction display unit 16 does not display the instruction information. Specifically, when the instruction number “99” is determined, the instruction indicator 16 turns off during the period in which the instruction information is displayed. According to the above configuration, the stop operation mode is not instructed by the instruction display device 16 in the non-instruction period.

As shown in FIG. 17B, when the batting order replay X1 is won in each game in the instruction period, the main CPU 301 determines the instruction number “01”. When the instruction number “01” is determined, the main CPU 301 causes the instruction display device 16 to display the number “1” (hereinafter, referred to as “instruction information “1””) as instruction information. As described above, when the batting order replay X1 is won, the correct answer pressing order for the RT2 transition replay (the pressing order for promoting from the RT1 state to the RT2 state) is “left middle right”. In the above configuration, in the game in which the instruction information “1” is displayed, the case where the stop operation is performed in the order of “left middle right” is more advantageous than the case where the stop operation is performed in another order. Therefore, when the instruction information “1” is displayed on the instruction display device 16, the player performs the stop operation in the order of “left middle right”. In other words, in the above configuration, by displaying the instruction information “1”, the player is instructed to perform the stop operation in the order of “left middle right”.

As shown in FIG. 17B, when the batting order replay X2 is won in each game of the instruction period, the main CPU 301 determines the instruction number “02”. When the instruction number “02” is determined, the main CPU 301 causes the instruction display device 16 to display the number “2” (hereinafter referred to as “instruction information “2””) as instruction information. As described above, when the batting order replay X2 is won, the correct answer pressing order of the RT2 transition replay is "left and right middle". In the above configuration, in the game in which the instruction information “2” is displayed, it is more advantageous when the stop operation is performed in the order of “left and right middle” than when the stop operation is performed in another order. Therefore, when the instruction information “2” is displayed on the instruction display device 16, the player performs the stop operation in the order of “left and right middle”. In other words, in the above configuration, by displaying the instruction information “2”, the player is instructed to perform the stop operation in the order of “right and left middle”.

As shown in FIG. 17B, when the batting order replay X3 is won in each game of the instruction period, the main CPU 301 determines the instruction number “03”. When the instruction number “03” is determined, the main CPU 301 causes the instruction display device 16 to display the number “3” (hereinafter, referred to as “instruction information “3””) as instruction information. As described above, when the batting order replay X3 is won, the correct pressing order for the RT2 transition replay is "middle left and right". In the above configuration, in the game in which the instruction information “3” is displayed, it is more advantageous when the stop operation is performed in the “middle left and right” order than when the stop operation is performed in another order. Therefore, when the instruction information “3” is displayed on the instruction display device 16, the player performs the stop operation in the order of “middle left and right”. In other words, in the above configuration, by displaying the instruction information “3”, the player is instructed to perform the stop operation in the order of “middle left and right”.

As shown in FIG. 17B, when the batting order replay X4 is won in each game of the instruction period, the main CPU 301 determines the instruction number “04”. When the instruction number “04” is determined, the main CPU 301 causes the instruction display unit 16 to display the number “4” (hereinafter referred to as “instruction information “4””) as instruction information. As described above, when the batting order replay X4 is won, the correct pressing order for the RT2 transition replay is "middle right left". In the above configuration, in the game in which the instruction information “4” is displayed, the case where the stop operation is performed in the order of “middle right left” is more advantageous than the case where the stop operation is performed in another order. Therefore, when the instruction information “4” is displayed on the instruction display device 16, the player performs the stop operation in the order of “middle right left”. In other words, by displaying the instruction information “4”, the above configuration instructs the player to perform the stop operation in the order of “middle right, left”.

As shown in FIG. 17B, when the batting order replay X5 is won in each game of the instruction period, the main CPU 301 determines the instruction number “05”. When the instruction number “05” is determined, the main CPU 301 causes the instruction display device 16 to display the number “5” (hereinafter referred to as “instruction information “5””) as instruction information. As described above, when the batting order replay X5 is won, the correct answer pressing order of the RT2 transition replay is "right left middle". In the above configuration, in the game in which the instruction information “5” is displayed, the case where the stop operation is performed in the order of “right middle left” is more advantageous than the case where the stop operation is performed in another order. Therefore, when the instruction information “5” is displayed on the instruction display device 16, the player performs the stop operation in the order of “middle right, left”. In other words, in the above configuration, by displaying the instruction information “5”, the player is instructed to perform the stop operation in the order of “right left middle”.

As shown in FIG. 17B, when the batting order replay X6 is won in each game of the instruction period, the main CPU 301 determines the instruction number “06”. When the instruction number “06” is determined, the main CPU 301 causes the instruction display unit 16 to display the number “6” (hereinafter referred to as “instruction information “6””) as instruction information. As described above, when the batting order replay X6 is won, the correct answer pressing order of the RT2 transition replay is "right middle left". With the above configuration, in the game in which the instruction information “6” is displayed, the case where the stop operation is performed in the order of “right middle left” is more advantageous than the case where the stop operation is performed in another order. Therefore, when the instruction information “6” is displayed on the instruction display device 16, the player performs the stop operation in the order of “right middle left”. In other words, in the above configuration, by displaying the instruction information “6”, the player is instructed to perform the stop operation in the order of “right middle left”.

As shown in FIG. 17B, when the batting order replay Y1 or the batting order bell L (1 to 4) is won in each game of the instruction period, the main CPU 301 determines the instruction number “07”. When the instruction number “07” is determined, the main CPU 301 causes the instruction display device 16 to display the number “7” (hereinafter, referred to as “instruction information “7””) as instruction information. As described above, when the batting order replay Y1 is won, the correct pressing order of the RT3 transition replay is the left first stop. Further, when the batting order bell L is won, the correct answer pressing order of the correct answer bell is the left first stop. As can be understood from the above description, in the game in which the instruction information “7” is displayed, the case where the stop operation is performed by the first left stop is more advantageous than the case where the stop operation is performed in another order. Therefore, when the instruction information “7” is displayed on the instruction display device 16, the player performs a stop operation at the first left stop. In other words, by displaying the instruction information “7”, the configuration described above instructs the player to perform a stop operation at the first left stop.

As shown in FIG. 17B, when the batting order replay Y2 or the batting order bell C(1 to 4) is won in each game of the instruction period, the main CPU 301 determines the instruction number “08”. When the instruction number “08” is determined, the main CPU 301 causes the instruction display device 16 to display the number “8” (hereinafter referred to as “instruction information “8””) as instruction information. As described above, when the batting order replay Y2 is won, the correct pressing order for the RT3 transition replay is the middle first stop. Further, when the batting order bell C is won, the correct answer pressing order of the correct answer bell is the middle first stop. As can be understood from the above description, in the game in which the instruction information “8” is displayed, the case where the stop operation is performed in the middle first stop is more advantageous than the case where the stop operation is performed in another order. Therefore, when the instruction information “8” is displayed on the instruction display device 16, the player performs a stop operation at the first middle stop. In other words, in the above configuration, by displaying the instruction information “8”, the player is instructed to perform the stop operation with the middle first stop.

As shown in FIG. 17B, when the batting order replay Y3 or the batting order bell R (1 to 4) is won in each game of the instruction period, the main CPU 301 determines the instruction number “09”. When the instruction number “09” is determined, the main CPU 301 causes the instruction display device 16 to display the number “9” (hereinafter referred to as “instruction information “9””) as instruction information. As described above, when the batting order replay Y3 is won, the correct pressing order for the RT3 transition replay is the right first stop. When the batting order bell R is won, the correct answer pressing order of the correct answer bell is the first stop on the right. As can be understood from the above description, in the game in which the instruction information “9” is displayed, the case where the stop operation is performed at the first right stop is more advantageous than the case where the stop operation is performed in another order. Therefore, when the instruction information “9” is displayed on the instruction display device 16, the player performs a stop operation at the right first stop. In other words, by displaying the instruction information “9”, the configuration described above instructs the player to perform a stop operation at the first right stop. When the batting order replay or a batting order bell is won in the instruction period, the main CPU 301 determines the instruction number “99”, and the instruction display unit 16 does not display the instruction information.

FIG. 17C is a schematic diagram of the segment display D. The segment display D includes the above-described instruction display 16. The indicator 16 is a one-digit 7-segment display. FIG. 17C illustrates the instruction display device 16 that displays the instruction information “1”.

As shown in FIG. 17C, the segment display D includes a regulation period display 38. The regulation period indicator 38 is in an ON state (lighted) during the regulation period. As described above, each instruction period (start preparation state, AT state, part of chance state) is included in the regulation period. Therefore, during the instruction period in which the instruction information is displayed on the instruction display device 16, the regulation period display device 38 lights up. In the present embodiment, the regulation period indicator 38 is not lit in the termination preparation state, but the regulation period indicator 38 may be lit in the termination preparation state.

FIG. 18 is a diagram for explaining each command (first command, second command) transmitted from the main CPU 301 to the sub CPU 412. The main CPU 301 transmits various commands including the first command and the second command to the sub CPU 412 during a period from the time when the game is started to the time when the game can be stopped.

As shown in FIG. 18, the main CPU 301 transmits the first commands “A00” to “A13” to the sub CPU 412 according to the winning area. For example, when the winning area of the game this time is lost, the main CPU 301 transmits the command “A00” to the sub CPU 412. Further, when the batting order replay (X1 to X6, Y1 to Y3) is won, the main CPU 301 transmits a command “A01”. Further, the main CPU 301 transmits a command “A02” when the BAR replay is won, and transmits a command “A03” when the normal replay is won. The main CPU 301 transmits a command “A04” when the batting order bells (L1 to L4, C1 to C4, R1 to R4) are won, and a command “A05” when the common bell is won. The main CPU 301 transmits a command “A06” when the watermelon is elected, a command “A07” when the weak cherry is elected, and a command “A08” when the strong cherry is elected, indicating a weak chance. When the eye is won, the command “A09” is transmitted, and when the strong chance is won, the command “A10” is transmitted. Similarly, the main CPU 301 transmits the command “A11” when the small winning role ALL is won, the command “A12” when the BB is won, and the command “A13” when the RB is won. Is sent.

When receiving the above first command, the sub CPU 412 determines various effects according to the first command. For example, when the command “A06” when the watermelon is won is received, the sub CPU 412 determines an effect for notifying that the watermelon is won.

In addition to the first command, the main CPU 301 transmits a second command (B01 to B09, B99) corresponding to the instruction number (instruction information) of this game to the sub CPU 412. Specifically, when the instruction number "99" (no instruction) is determined in this game, the main CPU 301 transmits a command "B99" to the sub CPU 412, as shown in FIG. As described above, the instruction number "99" is determined for each game in the normal state. Therefore, in the non-instruction period, the command "B99" is transmitted in each game. Further, the instruction number "99" is determined when the winning area (miss, etc.) other than the batting order replay (X, Y) and the batting order bell (L, C, R) is won in the instruction period.

As shown in FIG. 18, the main CPU 301 transmits a command “B01” when the batting order replay X1 is won and the instruction number “01” (left-middle-right order) is determined in the instruction period. Further, when the batting order replay X2 is elected in the instruction period and the instruction number "02" (right and left middle order) is determined, the main CPU 301 transmits the command "B02", the batting order replay X3 is elected, and the instruction number. If "03" (middle left/right order) is determined, command "B03" is transmitted, batting order replay X4 is won, and if instruction number "04" (middle right left order) is determined, command "B04" is issued. If the batting order replay X5 is won and the instruction number "05" (right, middle left) is determined, the command "B05" is transmitted, the batting order replay X6 is won, and the instruction number "06" (right middle left). Command), the command “B06” is transmitted.

As shown in FIG. 18, when the batting order replay Y1 or the batting order bell L (1 to 4) is won in the instruction period and the instruction number “07” (first left stop) is determined, the main CPU 301 issues the command “B07”. Is sent. Further, when the batting order replay Y2 or the batting order bell C (1 to 4) is won in the instruction period and the instruction number “08” (first stop in the middle) is determined, the main CPU 301 transmits the command “B08”. Further, when the batting order replay Y3 or the batting order bell R(1 to 4) is won in the instruction period and the instruction number “09” (first stop on the right side) is determined, the main CPU 301 transmits the command “B09”.

When the above second command is received by the sub CPU 412, the sub CPU 412 determines an instruction effect for instructing the stop operation sequence of the instruction numbers specified by the second command. In the instruction effect, for example, the liquid crystal display device 30 instructs the same stop operation sequence as the stop operation sequence instructed by the instruction information. As described above, the second command transmitted in the non-instruction period is only the command “B99” (no instruction). Therefore, in principle, the instruction effect is not executed in the non-instruction period. However, it is also possible to have a configuration in which an effect that instructs a stop operation sequence that does not affect (ball impact is small) is executed.

FIG. 19A and FIG. 19B are conceptual diagrams of the respective barrel effect determination tables (A, B). The main CPU 301 determines whether or not to execute each rotating body effect in the rotating body effect determination process. In the spinning drum effect, the main CPU 301 changes each reel 12 in a predetermined manner. Each spinning drum effect includes a spinning drum effect A, a spinning drum effect B, a spinning drum effect C, and a spinning drum effect D, and the mode of each reel 12 is different for each spinning drum effect. It should be noted that the mode of each reel 12 in each spinning drum effect can be appropriately changed.

The main CPU 301 determines the rotating body effect using the rotating body effect determination table A in each game in the normal state. In addition, the main CPU 301 determines the spinning effect by using the spinning effect determination table B in each game in the AT state.

As shown in FIG. 19, each barrel effect determination table is configured to include each lottery value for each winning area. In addition, each lottery value includes a lottery value of “no effect”, a lottery value of the spinning drum production A, a lottery value of the spinning drum production B, a lottery value of the spinning drum production C, and a lottery value of the spinning drum production D. There is. Each lottery value is in the order of "no effect" to the revolving cylinder effect D in the revolving speed effect determination process (the order of no effect→revolving speed effect A→revolving speed effect B→reducing speed effect C→reducing speed effect D). The random number value R2 (0 to 255) is subtracted. The main CPU 301 determines the spinning drum effect of the lottery value for which the subtraction result is a negative number. For example, it is assumed that a rare combination (cherry combination, watermelon combination, chance opportunity) is won and the random number value R2 is the numerical value “200” in the non-designation period. When the rare combination is won in the non-instruction period, as shown in FIG. 19, the lottery value “228” of “no effect” is subtracted from the random number value R2. In the above case, the result (200−228=−28) obtained by subtracting the lottery value of the rare combination from the random number value R2 is a negative number, so the main CPU 301 determines not to execute the rotating body effect in this game. . Further, for example, it is assumed that the rare combination is won and the random number value R2 is the numerical value “230” in the non-designation period. In the above case, the result (230-228=2) of subtracting the lottery value of "no effect" from the random number value R2 does not become a negative number, and then the lottery value "12" of the spinning drum effect A is subtracted from the subtraction result. If you do, it will be negative. Therefore, the main CPU 301 determines the rotating body effect A.

The main CPU 301 transmits, to the sub CPU 412, an effect type command indicating the spinner effect determined in each game. The effect type command is transmitted in the period from the time point of the game start operation to the time point when the stop operation becomes possible, like the first command and the second command described above. In addition, the transmission timing of the effect type command can be changed appropriately.

As described above, the main CPU 301 calculates various game information (bonus ratio, BB ratio, latest bonus ratio, latest BB ratio, regulation period ratio) according to the progress of the game, and displays the display information according to the game information. It is displayed on the main display 40. In order to calculate the above game information, the main CPU 301 counts the number of games in a period from when the power is first turned on to the gaming machine 1 to when the number of games reaches 175,000 (hereinafter referred to as “total game counting period”). To do.

In this embodiment, the ratio of the number of medals obtained in the bonus operation state in the total game counting period to the total payout number in the total game counting period (bonus ratio), and the number of medals obtained in the BB state in the total game counting period are The ratio (BB ratio) of the total payout number in the total game counting period is displayed on the main display 40. Further, the ratio of the number of games played in the restricted period to the total game counting period (restricted period ratio) is displayed on the main display 40.

Further, in the present embodiment, the ratio of the number of medals acquired in the bonus operation state in the latest 6000 game periods to the total payout amount in the game period (latest bonus ratio), BB in the latest 6000 game periods. The ratio (latest BB ratio) of the number of medals acquired in the state to the total payout number in the game period is displayed on the main display 40. In order to display the above bonus ratio, BB ratio, latest bonus ratio, latest BB ratio, and regulation period ratio on the main display 40, each storage area (ring buffer X) for storing various game information (payout number, number of games) To Z, set cumulative storage areas ac, total cumulative storage areas AC, restricted period storage area D, and total game storage area E) are provided. The above storage areas are provided in, for example, the main RAM 303. Each storage area will be described in detail below.

FIG. 20(a-1) is a diagram for explaining each unit storage area x (1 to 15), the set total storage area a, and the total total storage area A. Each unit storage area x is provided with fifteen unit storage areas x1 to x15. Each of the unit storage areas x is, for example, a storage area of 2 bytes. Each of the above unit storage areas x constitutes a ring buffer X. With the above configuration, the size of the ring buffer X is 30 (2×15) bytes.

FIG. 20A-2 is a conceptual diagram of the ring buffer X (each unit storage area x), the set total storage area a, and the total total storage area A. 20(a-2), and FIG. 20(b-2), FIG. 20(c-2) and FIG. Means the number stored in.

Each of the unit storage areas x stores the number of payouts during a series of 400 game periods (hereinafter referred to as “one set”) (see FIG. 20(a-1)). For example, the payout number of the current set (the last 400 games) is stored in the unit storage area x1. Further, the payout number of the previous set (401 to 800 times before the game) is stored in the unit storage area x2, and the payout number of the set 3 times before (the game before 801 to 1200 times) is stored in the unit storage area x3. To be done. Similarly, each of the payout numbers from the set 4 times before (game 1201 to 1600 times ago) to the set 15 times ago (game 5601 to 6000 times ago) is the unit storage area x4 to the unit storage area x15, respectively. Memorized in. Hereinafter, for the sake of explanation, a set (current set) in which the payout number is stored in the unit storage area x1 is referred to as a “set S1”. Similarly, each set in which the payout number is stored in each of the unit storage area x2 to the unit storage area x15 is referred to as "set S2" to "set S15".

In the specific example of FIG. 20A-2, for example, it is assumed that a total of 757 medals have been paid out in the set S1. The number of bet medals required for one game is three regardless of the game state. Moreover, in the re-play (the next play in which the re-play is stopped), the bet medal is unnecessary. Therefore, when the replay game is executed N times (N is a positive integer) in the set S1, a total of 1200-3N (3×400-3N) medals are obtained in one set (400 times) of the game. It is thrown in. If the replay game is executed 60 times (N=60) in the set S1, the total number of bet medals in the set S1 is 1020. In the above case, in the set S1 in the specific example of FIG. 20(a-2), the net additional number obtained by subtracting the total bet medals (1020) from the total payout number (757) is 263. On the other hand, for example, since the total payout number in the set S6 is 1564, if the replay game is executed 60 times in the set S6, the net additional number in the set S6 becomes 544 plus.

As shown in FIG. 20(a-1), the set cumulative storage area a stores the total number of payouts in the most recent 15 sets (6000 games). The set cumulative storage area a is, for example, a 3-byte storage area. As described above, each of the unit storage areas x of the ring buffer X stores the latest 15 sets of payout numbers. Therefore, when the total number of payouts in each unit storage area x of the ring buffer X is summed up, the total number of payouts in the latest 15 sets is obtained. As will be described later in detail, the main CPU 301 stores the total payout number stored in each unit storage area x of the ring buffer X in the set total storage area a each time each set is completed (every 400 games). ..

As shown in FIG. 20(a-1), the total cumulative storage area A stores the total number of medals (total payout number) paid out in each game in the total game counting period. The total cumulative storage area A is, for example, a 4-byte storage area. The main CPU 301 adds the number of payouts in the set to the total cumulative storage area A each time each set is completed. However, when the total game counting period ends (when 175000 games have been executed), the total cumulative storage area A is not updated (added) thereafter.

As will be described later in detail, when the total number of games is 6000 or less, the set cumulative storage area a and the total cumulative storage area A have the same payout number. On the other hand, when the total number of games exceeds 6000 times (specifically, when it exceeds 6400 times), the payout number in the total cumulative storage area A becomes larger than the payout number in the set cumulative storage area a. For example, in the specific example of FIG. 20A-2, the payout number (18867) in the total cumulative storage area A is larger than the payout number (17826) in the set cumulative storage area a. That is, the specific example of FIG. 20(a-2) assumes a case where the total game period is longer than 6000 times.

FIG. 20(b-1) is a diagram for explaining each unit storage area y (1 to 15), set cumulative storage area b, and total cumulative storage area B. Fifteen unit storage areas y1 to y15 are provided for each unit storage area y. Each of the unit storage areas y is, for example, a storage area of 2 bytes. Each of the above unit storage areas y constitutes a ring buffer Y. With the above configuration, the size of the ring buffer Y is 30 (2×15) bytes.

FIG. 20B-2 is a conceptual diagram of the ring buffer Y (each unit storage area y), the set total storage area b, and the total total storage area B. Each of the unit storage areas y of the ring buffer Y stores each of the payout numbers in the bonus operation state in each set (see FIG. 20(b-1)). That is, the payout number stored in each unit storage area y does not include the medals paid out in the gaming state other than the bonus operating state. For example, the unit storage area y is not added even when the watermelon combination wins in the normal state and five medals are paid out. On the other hand, when the correct answer bell is won and nine medals are paid out in the bonus operation state, the numerical value “9” is added to the unit storage area y.

Each of the unit storage areas y1 to y15 corresponds to each of the unit storage areas x1 to x15. The number of payouts in the bonus operation state in each of the sets S1 to S15 is stored in each of the unit storage areas y1 to y15. In the above configuration, among the payout numbers stored in each unit storage area x, the payout number in the bonus operation state is stored in the unit storage area y corresponding to the unit storage area x.

For example, in the specific example of FIG. 20B-2, the payout number stored in the unit storage area y5 is the numerical value “0”. In the above specific example, it is assumed that the bonus operation state is not set in the set S5 (the bonus combination is not won). In the above case, the payout number stored in the unit storage area x5 does not include the medals paid out in the bonus operation state. On the other hand, in the specific example of FIG. 20B-2, 72 payout numbers are stored in the unit storage area y1. As described above, when the correct answer bell (the payout number is 9) wins eight times, the RB state ends, so that the total payout number in the RB state is 72. In the specific example of FIG. 20(b-2), it is assumed that, in the set S1, the RB state is shifted once and 72 (9×8) medals are paid out in the bonus operation state.

Even if the bonus combination (BB combination and RB combination) is not won in the current set, the number of payouts in the set may not be 0 depending on the bonus operation state. For example, in the specific example of FIG. 20B-2, it is assumed that the state shifts to the BB state at the end of the set S11 and the set S11 ends in the middle of the BB state. In the above case, since the BB state continues in the first game of the set S12, even if the bonus combination is not won in the set S12, the payout number in the bonus operation state in the set S12 is more than 0.

As shown in FIG. 20(b-1), the set cumulative storage area b stores the total number of medals paid out in the bonus operation state in the last 15 sets (6000 times of games). In each of the unit storage areas y of the ring buffer Y, the respective payout numbers in the bonus operation state in the latest 15 sets are stored. Therefore, when the total number of payouts stored in each unit storage area y of the ring buffer Y is totaled, the total number of payouts in the bonus operation state in the latest 15 sets is obtained. As will be described later in detail, the main CPU 301 stores in the set cumulative storage area b the total number of payouts stored in each unit storage area y of the ring buffer Y every time each set is completed (every 400 games). To do.

As shown in FIG. 20(b-1), the total cumulative storage area B stores the total number of medals paid out in the bonus operation state during the total game counting period. The total cumulative storage area B is, for example, a 4-byte storage area. Each time the main CPU 301 finishes each set, the main CPU 301 adds the payout number in the bonus operation state of the set to the total cumulative storage area B. However, when the total game counting period ends (when 175000 games have been executed), the total cumulative storage area B is not updated (added) thereafter (similar to the total cumulative storage area A described above).

In the above configuration, the total number of medals paid out in each game in all game states in the total game counting period is stored in the total cumulative storage area A, and the total number of medals stored in the total cumulative storage area A is stored. The total number of medals paid out in each game in the bonus operation state among the number of coins is counted in the total cumulative storage area B.

As will be described later in detail, when the total number of games is 6000 times or less, the set total storage area b and the total total storage area B described above have the same payout number. On the other hand, when the total number of games exceeds 6000 times (specifically, when it exceeds 6400 times), the payout number in the total cumulative storage area B becomes larger than the payout number in the set cumulative storage area b. For example, in the specific example of FIG. 20B-2, the payout number (3996) in the total cumulative storage region B is larger than the payout number (3699) in the set cumulative storage region b. That is, the specific example of FIG. 20B-2 assumes a case where the total game period is longer than 6000 times.

FIG. 20(c-1) is a diagram for explaining each unit storage area z(1 to 15), set cumulative storage area c, and total cumulative storage area C. Each unit storage area z is provided with fifteen unit storage areas z1 to z15. Each of the unit storage areas z is, for example, a storage area of 2 bytes. Each of the above unit storage areas z constitutes a ring buffer Z. With the above configuration, the size of the ring buffer Z is 30 (2×15) bytes.

FIG. 20C-2 is a conceptual diagram of the ring buffer Z (each unit storage area z), the set total storage area c, and the total total storage area C. Each of the unit storage areas z of the ring buffer Z stores each of the payout numbers in the BB state in each set (see FIG. 20(c-1)). That is, the payout number stored in each unit storage area z does not include the medals paid out in the gaming state other than the BB state. For example, even when the correct answer bell is won in the RB state (not the BB state) when the symbol combination of the RB combination is stopped and displayed, the unit storage area z is not added. On the other hand, in the RB state in the BB state, the unit storage area z is added.

Each of the unit storage areas z1 to z15 corresponds to each of the unit storage areas x1 to x15. The payout number in the BB state in each of the sets S1 to S15 is stored in each of the unit storage areas z1 to z15. In the above configuration, the payout number in the BB state among the payout numbers stored in each unit storage area x is stored in the unit storage area z corresponding to the unit storage area x.

For example, as in the specific example of FIG. 20(b-2) described above, it is assumed that, in the set S1, the state has transitioned to the RB state once and has not transitioned to the BB state. In the above case, as shown in FIG. 20B-2, the unit storage area y1 is added to the numerical value “72”. On the other hand, the unit storage area z is not added to the set that has transitioned to the RB state and has not transitioned to the BB state. Therefore, even if the state shifts to the RB state in the set S1, if the state does not shift to the BB state in the set S1, the unit storage area z1 is the numerical value “0” as shown in FIG. 20(c-2). .

As shown in FIG. 20(c-1), the set cumulative storage area c stores the total number of medals paid out in the BB state in the most recent 15 sets (6000 games). Each of the unit storage areas z of the ring buffer Z stores each of the payout numbers in the BB state in the latest 15 sets. Therefore, when the total number of payouts stored in each unit storage area z of the ring buffer Z is summed, the total number of payouts in the BB state in the latest 15 sets is obtained. As will be described later in detail, the main CPU 301 stores the total payout number stored in each unit storage area z of the ring buffer Z in the set cumulative storage area c every time each set is completed (every 400 games). To do.

As shown in FIG. 20(c-1), the total cumulative storage area C stores the total number of medals paid out in the BB state of the total game counting period. The total cumulative storage area C is, for example, a 4-byte storage area. The main CPU 301 adds the number of payouts in the BB state of the set to the total cumulative storage area C each time the set is completed. However, when the total game counting period has ended (when 175,000 games have been executed), the total cumulative storage area C is not updated thereafter (similar to the total cumulative storage area A and the total cumulative storage area B described above). .. In the above configuration, the total number of medals paid out in each game in all game states in the total game counting period is stored in the total cumulative storage area A, and the total number of medals stored in the total cumulative storage area A is stored. The total number of medals paid out in each game in the BB state out of the number of coins is counted in the total cumulative storage area C.

As will be described later in detail, when the total number of games is 6000 times or less, the set total storage area c and the total total storage area C described above have the same payout number. On the other hand, when the total number of games exceeds 6000 times (specifically, when it exceeds 6400 times), the payout number in the total cumulative storage area C is larger than the payout number in the set cumulative storage area c. For example, in the specific example of FIG. 20(c-2), the payout number in the total cumulative storage area C (3564) is larger than the payout number in the set cumulative storage area c (3267). That is, the specific example of FIG. 20(c-2) assumes a case where the total game period is longer than 6000 times.

FIG. 20D is a diagram for explaining the restriction period storage area D and the total game storage area E. The regulation period storage area D stores the number of games played in the regulation period (AT state or the like) in the total game counting period. In addition, the total game storage area E stores the total number of games. The main CPU 301 adds the numerical value “1” to the total game storage area E in each game. Further, the main CPU 301 adds the numerical value “1” to the restriction period storage area D in each game of the restriction period.

The total game storage area E has a numerical value "0" at the first power-on, and thereafter is added up to the upper limit value "175000". That is, the total game storage area E counts the number of games in the total game counting period. Further, when the total game counting period ends (when the total number of games reaches 175,000), the addition of the total game storage area E is stopped. Further, in the regulation period storage area D, similarly to each of the total cumulative storage areas (A to C) described above, when the total game counting period ends (total game storage area E=175000), addition is stopped. In the above configuration, the regulation period storage area D stores the number of games in the regulation period in the total game counting period.

The main CPU 301 uses the set total storage area (a to c), total total storage area (A to C), restricted period storage area D or total game storage area E to calculate the bonus ratio, the BB ratio, and the latest bonus ratio. , The latest BB ratio and the regulation period ratio are calculated. Further, the main CPU 301 stores each game information in each of the ratio storage areas (H1 to H3, h1 and h2). Each ratio storage area is provided in the main RAM 303, for example.

FIG. 21 shows each storage area (ring buffer (X to Z), set cumulative storage area (ac), total cumulative storage area (A to) immediately after the end of each set (1, 2, 15, 16). It is a conceptual diagram of C)). Hereinafter, a specific example of the numerical values stored in each storage area in each set will be described with reference to FIG.

FIG. 21A shows a specific example of each storage area immediately after the first set is finished after the power is first turned on (at the time when the total number of games reaches 400 times). In this embodiment, at the time when the power of the gaming machine 1 is first turned on, the ring buffers (X to Z), the set cumulative storage areas (a to c), and the total cumulative storage areas (A to C) are , The initial value “0” is stored. After that, when the game of the first set is executed and the medals are paid out, the unit storage areas (x1, y1, z1) are added.

In the specific example of FIG. 21A, it is assumed that the unit storage area x1 has been added up to the numerical value “841” at the time when the first set is completed. In addition, in the specific example of FIG. 21A, it is assumed that the BB state is changed once in the first set, a total of 297 medals are paid out, and the RB state is not changed in the first set. To do. In the above case, the unit storage area y1 is added to the numerical value “297” and the unit storage area z1 is added to the numerical value “297” when the first set is completed. As shown in FIG. 21A, immediately after the completion of the first set, the unit storage areas x (2 to 15) other than the unit storage area x1 of the ring buffer X and the unit storage areas other than the unit storage area y1 of the ring buffer Y are stored. The area y (2 to 15) and the unit storage areas z (2 to 15) other than the unit storage area z1 of the ring buffer Z have the initial value “0”.

When the current set is completed, the sum of the numerical values stored in each unit storage area x (1 to 15) is stored in the set cumulative storage area a. Immediately after the completion of the first set, the value is "0" except for the unit storage area x1. Therefore, in the specific example of FIG. 21A, the numerical value “841” is stored in the set cumulative storage area a. When the current set is completed, the sum of the numerical values stored in each unit storage area y (1 to 15) is stored in the set cumulative storage area b. In the specific example of FIG. 21A, the numerical value “297” is stored in the set cumulative storage area b. Furthermore, when the current set is completed, the sum of the numerical values stored in each unit storage area z (1 to 15) is stored in the set cumulative storage area c. In the specific example of FIG. 21A, the numerical value “297” is stored in the set cumulative storage area c.

When the current set is completed, the number of medals paid out in the set (that is, the numerical value of the unit storage area x1) is added to the total cumulative storage area A. In the specific example of FIG. 21A, when the first set is completed, the total cumulative storage area A is added to the numerical value “841” from the initial value “0”. When the current set is completed, the number of medals paid out in the bonus operation state of the set (that is, the numerical value of the unit storage area y1) is added to the total cumulative storage area B. In the specific example of FIG. 21A, when the first set is finished, the total cumulative storage area B is added to the numerical value “297” from the initial value “0”. Further, when the current set is finished, the number of medals paid out in the BB state of the set (that is, the numerical value of the unit storage area z1) is added to the total cumulative storage area C. In the specific example of FIG. 21A, when the first set is completed, the total cumulative storage area C is added to the numerical value “297” from the initial value “0”.

FIG. 21B shows a specific example of each storage area immediately after the completion of the second set. In the specific example of FIG. 21B, similar to the specific example of FIG. 21A described above, it is assumed that the unit storage area x1 is added up to the numerical value “841” in the first set.

When the previous set is finished and the current set is started, the numerical value of the unit storage area xn (n is an integer of the numerical values “1 to 15”) is stored in the unit storage area xn+1. When the current set is started, the unit storage area x1 is cleared to the initial value "0", and the payout number of the current set is added to the unit storage area x1 as in the previous set. For example, as in the specific example of FIG. 21B, when the second set is started, the numerical value “841” of the unit storage area x1 in which the total payout number of the first set is stored is the unit storage area x2. Is stored (moved) in. When the current set is started, the numerical value stored in the unit storage area x15 (the number of payouts in the set 16 sets before) is discarded.

In the specific example of FIG. 21B, it is assumed that a total of 1801 medals are paid out in the second set. In the above case, immediately after the end of the second set, the unit storage area x1 has the numerical value “1801” and the unit storage area x2 has the numerical value “841”. Immediately after the completion of the second set, each unit storage area x (3 to 15) other than the unit storage area x1 and the unit storage area x2 has the initial value “0”. In the above specific example, when the second set is completed, the total value “2642” (=1801+841) of each unit storage area x of the ring buffer X is stored in the set total storage area a. In the above specific example, the numerical value “841” is added to the total cumulative storage area A when the first set is completed, and the numerical value “1801” is added to the total cumulative storage area A when the second set is completed. Is added, and the total cumulative storage area A becomes the numerical value “2642”.

In the specific example of FIG. 21B, similar to the specific example of FIG. 21A, it is assumed that the unit storage area y1 has been added up to the numerical value “297” in the first set. When the current setting is started, the numerical value of the unit storage area yn (n is an integer of numerical values “1 to 15”) is stored in the unit storage area yn+1. When the current set is started, the unit storage area y1 is cleared to the initial value “0”, and the number of payouts in the bonus operation state of the present set is added to the unit storage area y1 as in the previous set. To be done. For example, as in the specific example of FIG. 21B, when the second set is started, the value “297” in the unit storage area y1 in which the number of payouts in the bonus operation state of the first set is stored is the unit. It is stored (moved) in the storage area y2. When the current set is started, the numerical value stored in the unit storage area y15 (the number of payouts in the bonus operation state in the set 16 sets before) is discarded.

In the specific example of FIG. 21B, it is assumed that a total of 72 medals have been paid out in the second set bonus operation state. In the above case, immediately after the end of the second set, the unit storage area y1 has the numerical value "72" and the unit storage area y2 has the numerical value "297". Immediately after the completion of the second set, each unit storage area y (3 to 15) other than the unit storage area y1 and the unit storage area y2 has the initial value “0”. In the above specific example, when the second set is completed, the total value “396” (=72+297) of each unit storage area x of the ring buffer Y is stored in the set total storage area b. Further, in the above specific example, when the first set is finished, the numerical value “297” is added to the total cumulative storage area B, and when the second set is finished thereafter, the numerical value “72” is written in the total cumulative storage area B. Is added, and the total cumulative storage area B becomes the numerical value “396”.

In the specific example of FIG. 21B, similar to the specific example of FIG. 21A, it is assumed that the unit storage area z1 has been added up to the numerical value “297” in the first set. When the current set is started, the numerical value of the unit storage area zn (n is an integer of numerical values “1 to 15”) is stored in the unit storage area zn+1. When the current set is started, the unit storage area z1 is cleared to the initial value “0”, and the payout number in the BB state of the current set is added to the unit storage area z1 as in the previous set. It For example, when the second set is started as in the specific example of FIG. 21B, the numerical value “297” of the unit storage area z1 in which the number of payouts in the BB state of the first set is stored is the unit storage. It is stored (moved) in the area z2. When the current set is started, the numerical value stored in the unit storage area z15 (the number of payouts in the BB state in the set 16 sets before) is discarded.

In the specific example of FIG. 21B, it is assumed that the BB state is not entered in the second set. In the above case, immediately after the end of the second set, the unit storage area z1 has the numerical value "0" and the unit storage area z2 has the numerical value "297". Immediately after the completion of the second set, the unit storage areas z3 to z15 have the initial value "0". In the above specific example, when the second set is completed, the total value “297” (=0+297) of each unit storage area x of the ring buffer Z is stored in the set total storage area c. Further, in the above specific example, when the first set is finished, the numerical value “297” is added to the total cumulative storage area C, and when the second set is finished thereafter, the total cumulative storage area C is not added.

FIG. 21C is a conceptual diagram of each storage area immediately after the 15th set is completed. That is, FIG. 21C is a conceptual diagram of each storage area in the case where a game has been executed 6000 times since the power of the gaming machine 1 was first turned on. Immediately after the end of the 15th set, the unit storage area x1 of the ring buffer X stores the total payout number of the 15th set (latest), and the unit storage area x15 stores the payout number of the 1st set (oldest). Is stored. Similarly, immediately after the 15th set is finished, the total payout number in the bonus operation state of the 15th set is stored in the unit storage area y1 of the ring buffer Y, and the bonus operation of the first set is stored in the unit storage area y15. The total payout number in the state is stored. Immediately after the completion of the 15th set, the unit storage area z1 of the ring buffer Z stores the total payout number in the BB operating state of the 15th set, and the unit storage area z15 stores the BB state of the first set. The total payout number is stored.

As described above, the set total storage area a stores the sum of the numerical values of the unit storage areas x of the ring buffer X at the end of the current set. On the other hand, to the total cumulative storage area A, the numerical value of the unit storage area x1 at the end of each set is added. In the above configuration, up to the 15th set (total number of games≦6000), the set total storage area a and the total total storage area A have the same numerical value. Similarly, the set total storage area b stores the sum of the numerical values of the unit storage areas y of the ring buffer Y at the end of the current set. On the other hand, to the total cumulative storage area B, the numerical value of the unit storage area y1 at the end of each set is added. With the above configuration, the numerical values of the set cumulative storage area b and the total cumulative storage area B are the same up to the 15th set. The set total storage area c stores the sum of the numerical values of the unit storage areas z of the ring buffer Z at the end of the current set. On the other hand, to the total cumulative storage area C, the numerical value of the unit storage area z1 at the end of each set is added. With the above configuration, the numerical values of the set cumulative storage area b and the total cumulative storage area B are the same up to the 15th set.

FIG. 21D is a conceptual diagram of each storage area immediately after the 16th set is completed. That is, FIG. 21D is a conceptual diagram of each storage area when the total number of games reaches 6400. 21D, it is assumed that the numerical value (payout number) stored in each unit storage area x of the ring buffer X up to the 15th set is the same as the specific example of FIG. 21C. In the above case, the numerical values stored in the unit storage area x1 to the unit storage area x14 of the ring buffer X in FIG. 21(c) are the same as those stored in the unit storage area x2 of the ring buffer X in FIG. 21(d). It is stored in the unit storage area x15. Further, the numerical value stored in the unit storage area x15 of the ring buffer X shown in FIG. 21C described above is discarded when the 16th set is completed. As shown in FIG. 21D, the total value “757” of the payout number of the 16th set is newly stored in the unit storage area x1.

When the 16th set is finished, as in the case where the 15th set is finished, the sum of the numerical values of the unit storage areas x of the ring buffer X is stored in the set cumulative storage area a. In the specific example of FIG. 21D, the total value “17826” of payout numbers in the 15 most recent sets from the second set to the 16th set is stored in the set cumulative storage area a. As described above, the total payout number for the latest 15 sets from the 1st set to the 15th set is the numerical value "17910" (see FIG. 21(c)). Therefore, the total payout number for the latest 15 sets is 15 sets. This means that the 16th set has decreased compared to the eyes. However, immediately after the end of the 16th set, when the number of payouts discarded from the unit storage area x15 is smaller than the number of payouts added to the unit storage area x1, the total number of payouts in the latest 15 sets is 16th from the 15th set. It increases with the set eye.

When the 16th set is completed, the numerical value of the unit storage area x1 is added to the total cumulative storage area A, as in the case where the 15th set is completed. In the specific example of FIG. 21D, the total cumulative storage area A is added from the numerical value “17910” to the numerical value “18867” (=17910+757). As described above, the set cumulative storage area a indicating the total payout number of the last 15 sets increases or decreases at the end of each set, while the total cumulative storage area A indicating the total payout number increases each time the set ends. However, when the total number of games exceeds 175,000, the update of the total cumulative storage area A is stopped.

In the specific example of FIG. 21D, it is assumed that the numerical values (payout number) stored in each unit storage area y of the ring buffer Y up to the 15th set are the same as those in FIG. 21C. In the above case, the numerical values stored in the unit storage area y1 to the unit storage area y14 of the ring buffer Y in FIG. 21C are the same as those stored in the unit storage area y2 of the ring buffer Y in FIG. It is stored in the unit storage area y15. Further, in FIG. 21C described above, the numerical value stored in the unit storage area y15 of the ring buffer Y is discarded when the 16th set is completed. In FIG. 21D, the total value “72” of the number of payouts in the bonus operation state of the 16th set is newly stored in the unit storage area y1.

When the 16th set is finished, as in the case when the 15th set is finished, the sum of the numerical values of the unit storage areas y of the ring buffer Y is stored in the set cumulative storage area b. In the specific example of FIG. 21D, the total value “3699” of the number of payouts in the bonus operation state in the latest 15 sets from the second set to the 16th set is stored in the set cumulative storage area b. As described above, the total payout number for the latest 15 sets from the 1st set to the 15th set is the numerical value “3924” (see FIG. 21C). This means that the total decreased from the 15th set to the 16th set. However, immediately after the end of the 16th set, when the number of payouts discarded from the unit storage area y15 is smaller than the number of payouts added to the unit storage area y1, the total number of payouts in the bonus operation state in the last 15 sets is It increases from the 15th set to the 16th set.

When the 16th set is completed, the numerical value of the unit storage area y1 is added to the total cumulative storage area B as in the case where the 15th set is completed. In the specific example of FIG. 21D, the total cumulative storage area B is added from the numerical value “3924” to the numerical value “3996” (=3924+72). As described above, the total set storage area b indicating the total payout number in the bonus operation state of the last 15 sets increases or decreases at the end of each set, while the total total storage area B increases each time the set ends. However, when the total number of games exceeds 175,000, the update of the total cumulative storage area B is stopped. Further, in each set, when the bonus operation state is not entered (unit storage area y1=0), the total cumulative storage area B does not increase at the end of the set.

In the specific example of FIG. 21D, it is assumed that the numerical values (payout number) stored in each unit storage area z of the ring buffer Z up to the 15th set are the same as those in FIG. 21C. In the above case, the numerical values stored in the unit storage area z1 to the unit storage area z14 of the ring buffer Z in FIG. 21C described above are changed from the unit storage area z2 of the ring buffer Z in FIG. It is stored in the unit storage area z15. Further, in FIG. 21C described above, the numerical value stored in the unit storage area z5 of the ring buffer Z is discarded when the 16th set is completed. In FIG. 21D, it is assumed that the 16th set does not shift to the BB state. In the above case, the total value “0” of the payout number in the BB state is newly stored in the unit storage area z1.

When the 16th set is completed, as in the case where the 15th set is completed, the sum of the numerical values of the unit storage areas z of the ring buffer Z is stored in the set cumulative storage area c. In the specific example of FIG. 21D, the total value “3267” of the number of payouts in the BB state in the latest 15 sets from the second set to the 16th set is stored in the set cumulative storage area c. As described above, since the total payout number in the latest 15 sets from the 1st set to the 15th set is the numerical value “3564” (see FIG. 21C), the total payout number in the BB state in the latest 15 sets. Is decreased in the 16th set from the 15th set. However, immediately after the end of the 16th set, when the number of payouts discarded from the unit storage area z15 is smaller than the number of payouts added to the unit storage area z1, the total number of payouts in the BB state in the latest 15 sets is 15 It increases from the 16th set to the 16th set.

When the 16th set ends, the numerical value of the unit storage area z1 is added to the total cumulative storage area C, as in the case where the 15th set ends. In the specific example of FIG. 21D, the total cumulative storage area C is not calculated from the numerical value “3564”. However, the total cumulative storage area C is added in principle, unless the BB state is not entered in this set. As described above, the set cumulative storage area c indicating the total payout number in the BB state of the last 15 sets increases or decreases at the end of each set, while the total cumulative storage area C increases each time the set ends. However, when the total number of games exceeds 175,000, the update of the total cumulative storage area C is stopped.

In the present embodiment described above, the progress of the game is controlled in each of the sets (unit period) repeated for each predetermined number of games (400 times), and the payout number (game information) in one set is stored in each unit. In the configuration of storing in any of the areas, the payout number stored in the unit storage area is sequentially updated so that the payout number in each of the sets is stored in each unit storage area, and the unit storage means The main display 40 is capable of displaying according to the total value of the number of payouts stored in each. According to the above configuration, the number of payouts in each set is stored in each unit storage area. Therefore, since the payout number in each set is stored in a separate unit storage area, the payout number for each set can be specified by analyzing the numerical value stored in each unit storage area.

For example, assume that the number of payouts in a specific set is excessively large. In the above case, it is possible to specify that a medal may have been acquired by a fraudulent act in the set. As described above, by analyzing the number of payouts stored in each unit storage area, it is possible to verify the presence or absence of fraud in each set. Note that the game information other than the payout number may be stored in each unit storage area.

FIG. 22 is a diagram for explaining each ratio storage area. Each ratio storage area includes a ratio storage area G1, a ratio storage area G2, a ratio storage area G3, a ratio storage area g1, and a ratio storage area g2. The ratio storage area is a 1-byte storage area.

As shown in FIG. 22, the percentage storage area G1 stores the bonus percentage. As described above, the total payout number in the total game counting period is stored in the cumulative storage area A, and the total payout number in the bonus operation state in the total gaming counting period is stored in the total cumulative storage area B. The main CPU 301 calculates the ratio (%) of the number of payouts in the total cumulative storage area B to the total number of payouts in the total cumulative storage area A every time one set is completed, and the calculated result is used as a bonus rate in the ratio storage area. Store in G1. When the calculation result includes a decimal part, the main CPU 301 discards the decimal part and stores only the integer part in the ratio storage area G1. For example, when the ratio of the number of paid-out sheets in the total cumulative storage area B to the number of paid-out sheets in the total cumulative storage area A is 70.5%, the main CPU 301 stores the numerical value “70” in the ratio storage area G1 as a bonus rate.

As shown in FIG. 22, the ratio storage area G2 stores the BB ratio. As described above, the total payout number in the BB state during the total game counting period is stored in the total cumulative storage area C. The main CPU 301 calculates the ratio (%) of the number of paid-out sheets in the total cumulative storage area C to the number of paid-out sheets in the total cumulative storage area A every time one set is completed, and sets the calculation result as the BB rate in the ratio storage area. Store in G2. When the calculation result includes a decimal part, the main CPU 301 discards the decimal part and stores only the integer part in the ratio storage area G2.

As shown in FIG. 22, the ratio storage area G3 stores the restriction period ratio. As described above, the total number of games in the total game counting period is stored in the total game storage area E, and the total number of games in the restriction period in the total game counting period is stored in the restriction period storage area D. The main CPU 301 calculates the ratio (%) of the number of games played in the restricted period storage area D to the number of games played in the total game storage area E every time one game ends, and stores the calculation result as a restricted period ratio. It is stored in the area G3. When the calculation result includes a decimal part, the main CPU 301 discards the decimal part and stores only the integer part in the ratio storage area G3.

As described above, the update of the total cumulative storage area A and the total cumulative storage area B is stopped after the total game counting period (175,000 games) has elapsed. Therefore, in the period after the total game counting period has elapsed, the bonus ratio (total cumulative storage region B/total cumulative storage region A) stored in the ratio storage region G1 is not updated. Further, as described above, the update of the total cumulative storage area C is stopped after the total game counting period has elapsed. Therefore, in the period after the total game counting period has elapsed, the BB ratio (total cumulative storage region C/total cumulative storage region A) stored in the ratio storage region G2 is not updated. As described above, the update of the restriction period storage area D and the total game storage area E is stopped after the total game counting period has elapsed. Therefore, in the period after the total game counting period has elapsed, the regulation period ratio (regulation period storage region D/total game storage region E) stored in the ratio storage region G3 is not updated. In the present embodiment, the ratio storage area G1, the ratio storage area G2, and the ratio storage area G3, whose updating is stopped when the total game counting period elapses, may be collectively referred to as a “ratio storage area G”.

As shown in FIG. 22, the ratio storage area g1 stores the latest bonus ratio. As described above, the total payout number of the last 15 sets (6000 games) is stored in the set total storage area a, and the total payout number in the bonus operation state of the latest 15 sets is stored in the set total storage area b. Remembered. The main CPU 301 calculates the ratio (%) of the number of payouts in the set total storage area b to the number of payouts in the set total storage area a each time one set is completed, and the calculated result is used as the latest bonus ratio in the ratio storage area g1. Remember. When the calculation result includes a decimal part, the main CPU 301 discards the decimal part and stores only the integer part in the ratio storage area g1.

As shown in FIG. 22, the ratio storage area g2 stores the latest BB ratio. As described above, the total payout number in the BB state in the latest 15 sets is stored in the set cumulative storage area c. The main CPU 301 calculates the ratio (%) of the number of paid-out sheets in the set total storage area c to the number of paid-out sheets in the set total storage area a every time one set is completed, and sets the calculation result as the latest BB ratio in the ratio storage area g2. Remember. When the calculation result includes a decimal part, the main CPU 301 discards the decimal part and stores only the integer part in the ratio storage area g2.

As described above, the set total storage area a and the set total storage area b are continuously updated even after the total game counting period (175,000 games) has elapsed. Therefore, even in the period after the total game counting period has elapsed, the latest bonus rate stored in the rate storage area g1 is continuously updated (as described above, the update of the bonus rate is stopped). Further, the latest BB ratio is calculated from the payout number in the set total storage area a and the set total storage area c. As described above, the set cumulative storage area c is continuously updated even after the total game counting period has elapsed. Therefore, even in the period after the total game counting period has elapsed, the latest BB ratio stored in the ratio storage area g2 is continuously updated (the updating of the BB ratio is stopped). In the present embodiment, the ratio storage area g1 and the ratio storage area g2, which are continuously updated even when the total game counting period has elapsed, may be collectively referred to as “ratio storage area g”.

Each of the above ratio storage areas (G, g) is displayed on the main display 40 provided on the main control board 300. That is, the regulation period ratio, the latest bonus ratio, the latest BB ratio, the bonus ratio, and the BB ratio are displayed on the main display 40 provided on the main control board 300.

23A to 23E are diagrams for explaining each display information H(A to E). The main display 40 displays the regulation period ratio, the latest bonus ratio, the latest BB ratio, the bonus ratio, and the BB ratio according to each display information H. As shown in FIGS. 23A to 23E, each display information H includes display information HA, display information HB, display information HC, display information HD, and display information HE. 23(a) to 23(e) show simulated views of the main display 40. In FIG. 23A to FIG. 23E, among the segs of the main display 40, the segs that emit light are shaded.

The main display 40 switches and displays each display information H at predetermined time intervals. Specifically, when the power of the gaming machine 1 is turned on, the main display 40 starts displaying each display information H, and thereafter, displays each display information H about every 5 seconds until the power is turned off. Switch to and display. As shown in FIGS. 23A to 23E, each display information H includes identification information I(a to e) and ratio information R(a to e). Each piece of identification information I is displayed on the first display section 40X of the main display 40. Further, each ratio information R is displayed on the second display section 40Y of the main display 40.

FIG. 23A is a simulation diagram of the main display 40 that displays the display information HA of the display information H. As shown in FIG. 23A, the display information HA includes identification information Ia and ratio information Ra. The ratio information Ra of the display information HA displays the size of the regulation period ratio stored in the ratio storage area G3 described above. Specifically, the ratio information Ra can variably display the numbers “00” to “99” according to the size of the regulation period ratio. For example, when the regulation period ratio is 70%, the ratio information Ra displays the number "70". When the regulation period ratio is 100%, the ratio information Ra displays the number “99” as in the case where the regulation period ratio is 99%. As shown in FIG. 23A, the identification information Ia is a combination of the number “7” and the letter “U”, and makes it possible to identify that the number displayed by the ratio information Ra is the regulation period ratio.

FIG. 23B is a simulation diagram of the main display 40 that displays the display information HB among the display information H. As shown in FIG. 23B, the display information HB includes identification information Ib and ratio information Rb. The ratio information Rb of the display information HB displays the latest BB ratio stored in the ratio storage area g2 described above. Specifically, the ratio information Rb can variably display the numbers “00” to “99” according to the latest BB ratio. For example, when the latest BB ratio is 60%, the ratio information Rb displays the number "60". When the latest BB ratio is 100%, the ratio information Rb displays the number "99" as in the case where the latest BB ratio is 99%. As shown in FIG. 23B, the identification information Ib is a combination of the number “6” and the character “Y”, and makes it possible to identify that the number displayed by the ratio information Rb is the latest BB ratio.

FIG. 23C is a simulation diagram of the main display 40 that displays the display information HC among the display information H. As shown in FIG. 23C, the display information HC includes identification information Ic and ratio information Rc. The ratio information Rc of the display information HC displays the latest bonus ratio stored in the ratio storage area g1 described above. Specifically, the ratio information Rc can variably display the numbers “00” to “99” according to the latest bonus ratio. For example, when the latest bonus ratio is 70%, the ratio information Rc displays the number "70". When the latest bonus ratio is 100%, the ratio information Rc displays the number "99" as in the case where the latest bonus ratio is 99%. As shown in FIG. 23C, the identification information Ic is a combination of the number “7” and the character “Y”, and makes it possible to identify that the number displayed by the ratio information Rc is the latest bonus ratio.

FIG. 23D is a simulation diagram of the main display 40 that displays the display information HD among the display information H. As shown in FIG. 23D, the display information HD includes identification information Id and ratio information Rd. The ratio information Rd of the display information HD displays the BB ratio stored in the ratio storage area G2 described above. Specifically, the ratio information Rd can variably display the numbers "00" to "99" according to the BB ratio. For example, when the BB ratio is 60%, the ratio information Rd displays the number "60". When the BB ratio is 100%, the ratio information Rd displays the number "99" as in the case where the BB ratio is 99%. As shown in FIG. 23D, the identification information Id is a combination of the number “6” and the character “A”, and makes it possible to identify that the number displayed by the ratio information Rd is the BB ratio.

FIG. 23E is a simulation diagram of the main display 40 that displays the display information HE among the display information H. As shown in FIG. 23(e), the display information HE includes identification information Ie and ratio information Re. The ratio information Re of the display information HE displays the bonus ratio stored in the ratio storage area G1 described above. Specifically, the ratio information Re can variably display the numbers “00” to “99” according to the bonus ratio. For example, when the bonus ratio is 70%, the ratio information Re displays the number “70”. When the bonus ratio is 100%, the ratio information Re displays the number "99" as in the case where the bonus ratio is 99%. As shown in FIG. 23(e), the identification information Ie is a combination of the number "7" and the character "A", and makes it possible to identify that the number displayed by the ratio information Re is a bonus ratio.

According to the above configuration, the size of the regulation period ratio, the latest BB ratio, the latest bonus ratio, the BB ratio, and the bonus ratio is displayed by the display information H (ratio information R). Therefore, for example, the administrator of the gaming machine 1 confirms the main display 40 provided on the main control board 300 to determine the regulation period ratio, the latest BB ratio, the latest bonus ratio, the BB ratio, and the size of the bonus ratio. It can be confirmed whether or not is within a proper range.

Specifically, the probability of winning in the AT state is designed so that the regulation period ratio is usually about 70% or less. However, for example, if the program of the gaming machine 1 is deficient, there may occur a problem that the regulation period ratio when the player actually plays the game greatly exceeds about 70%. In the present embodiment, it is possible to confirm the presence or absence of the above-mentioned problems from the regulation period ratio displayed in the display information HA displayed on the main display 40. The winning probability (probability of transition to BB state and RB state) of the BB combination and the RB combination is usually designed so that the latest bonus ratio and the bonus ratio are about 70% or less. However, for example, if the program of the gaming machine 1 is deficient, there may occur a problem that the latest bonus rate or the bonus rate when the player actually plays the game greatly exceeds about 70%. In the present embodiment, the presence or absence of the above defects can be confirmed by the latest bonus rate and the bonus rate displayed on the display information HC and the display information HE displayed on the main display 40. Further, the winning probability (transition probability to the BB state) of the BB combination is usually designed so that the latest BB ratio and the BB ratio are about 60% or less. However, for example, if the program of the gaming machine 1 is deficient, there may occur a problem that the latest BB ratio or the BB ratio when the player actually plays the game greatly exceeds about 60%. In the present embodiment, the presence or absence of the above defects can be confirmed by the latest BB ratio and the BB ratio displayed on the display information HB and the display information HD displayed on the main display 40.

FIG. 24A is a diagram for explaining a display mode of the ratio information R. In the present embodiment, the respective ratios can be intuitively grasped as to whether or not the regulation period ratio, the latest BB ratio, the latest bonus ratio, the BB ratio and the bonus ratio are within appropriate ranges (whether or not there is the above-mentioned defect). The information R is displayed on the main display 40.

As shown in FIG. 24A, the main display 40 of the present embodiment displays the ratio information Ra (numerals “00” to “69”) indicating the restriction period ratio of less than 70% as “lighting” (lighting). Display mode). On the other hand, the main display 40 displays the ratio information Ra (numerals “70” to “99”) indicating the restriction period ratio of 70% or more in a “blinking” display mode (blinking display mode).

As shown in FIG. 24A, the main display 40 displays the ratio information Rb (numbers “00” to “59”) indicating the latest BB ratio of less than 60% in a lighting display mode. On the other hand, the main display 40 displays the ratio information Rb (numbers “60” to “99”) indicating the latest BB ratio of 60% or more in a blinking display mode. Similarly, the main display 40 displays the ratio information Rc indicating the latest bonus ratio of less than 70% in the lighting display mode, while displaying the ratio information Rc indicating the latest bonus ratio of 70% or more in the blinking display mode. , Ratio information Rd indicating a BB ratio of less than 60% is displayed in a lighting display mode, while ratio information Rd indicating a BB ratio of 60% or more is displayed in a blinking display mode, and a ratio indicating a bonus ratio of less than 70% While the information Re is displayed in the lighting display mode, the rate information Re indicating the bonus rate of 70% or more is displayed in the blinking display mode.

In the present embodiment, the numerical value of each ratio information R(a to e) changing from the lighting mode to the blinking mode is referred to as a threshold value of the ratio information R. As described above, the threshold values of the ratio information Ra, the ratio information Rc, and the ratio information Re are “70”. The threshold value of the ratio information Rb and the ratio information Rd is “60”.

FIG. 24(b-1) is a time chart for explaining a specific example of the ratio information R displayed in the lighting display mode. Further, FIG. 24B-2 is a time chart for explaining the ratio information R displayed in a blinking display mode. In FIG. 24(b-1) and FIG. 24(b-2), a simulated view of the second display unit 40Y of the main display 40 is extracted and shown. In FIG. 24(b-1) and FIG. 24(b-2), among the segs of the second display section 40Y, the segs that emit light are shaded.

As shown in FIG. 24(b-1), in the lighting display mode, each light-emitting segment that displays the divisor information R is maintained in a lighting state. In the specific example of FIG. 24(b-1), it is assumed that the divisor information R of the number “50” is displayed. In the above specific example, each segment that emits light to represent the number “50” is lit during the period in which the relevant divisor information R is displayed (about 5 seconds before switching to another divisor information R). Be maintained in a closed state.

As shown in FIG. 24(b-2), in the blinking display mode, each light-emitting segment that displays the divisor information R blinks at a predetermined time interval. Specifically, in the blinking display mode, each light-emitting segment that displays the divisor information R repeats lighting and extinguishing approximately every 0.6 seconds. In the specific example of FIG. 24(b-2), it is assumed that the divisor information R of the number “80” is displayed. In the above specific example, each segment that emits light to represent the number “80” is repeatedly turned on and off about every 0.6 seconds.

As described above, in the present embodiment, various types of game information (regulation period ratio, latest BB ratio, latest bonus ratio, BB ratio and bonus ratio) are updated according to the progress of the game, and the size of the game information is indicated. When the main display 40 (specific display means) capable of displaying the ratio information R (numerical value information) and the ratio information R have a size equal to or greater than a predetermined threshold value (60% or 70%), the ratio information R Is displayed in a blinking display mode (first display mode), and when the ratio information R indicates a size less than the threshold value, the ratio information R is displayed in a lighting display mode (second display mode). According to the above configuration, the display mode of each ratio information changes depending on whether or not the ratio information exceeds an appropriate threshold value, and thus it is intuitive to determine whether or not the ratio information exceeds the appropriate threshold value. To be able to grasp.

Further, in the present embodiment, the threshold value of the ratio information Ra at which the display mode of the main display 40 is switched is the numerical value “70”. As described above, the identification information Ia displayed on the main display 40 together with the ratio information Ra is “7U” and includes the number “7” (see FIG. 23A). Similarly, the thresholds of the ratio information Rc and the ratio information Re are numerical values “70”, and the identification information Ic “7Y” displayed together with the ratio information Rc and the identification information Ie displayed together with the ratio information Re. The number "7" is commonly included in "7A" (see FIG. 23(c) and FIG. 23(e)). Further, the threshold values of the ratio information Rb and the ratio information Rd are numerical values “60”, and the identification information Ib “6Y” displayed together with the ratio information Rb and the identification information Id “displayed together with the ratio information Rd”. The numeral "6" is commonly included in "6A" (see FIGS. 23C and 23E).

As can be understood from the above description, the threshold for switching the display mode is added to each piece of identification information I(a, c, e) displayed together with each piece of proportion information R(a, c, e) having the numerical value “70”. Includes the number “7” in common. Further, the identification information I(b, d) displayed together with the respective proportion information R(b, d) whose threshold for switching the display mode is the numerical value "60" includes the number "6" in common. Be done. In other words, the configuration described above includes that the instruction information I includes information corresponding to the threshold value of the ratio information R displayed as the instruction information I (the threshold value can be specified). According to the above configuration, since the threshold value of the ratio information R can be specified by the identification information I, it becomes easy to determine whether or not the ratio information R exceeds the threshold value.

As described above, the regulation period ratio is updated until the game is executed 175,000 times. That is, the ratio information Ra finally displays the restriction period ratio of 175,000 game periods. Further, the ratio information Ra displays the regulation period ratio in the game period of the current total number of games (<175,000) before the total number of games reaches 175,000.

In the above configuration, even if the ratio information Ra is inappropriate (70% or more) before the total number of games reaches 175,000, if the total number of games reaches 175000, the ratio information Ra is appropriate. The value may change (converge). In consideration of the above circumstances, in the present embodiment, it is possible to specify whether or not the ratio information Ra displays the final restriction period ratio (when the total number of games exceeds 175,000). Further, in the present embodiment, it is possible to specify whether or not the ratio information Rd (BB ratio) and the ratio information Re (bonus ratio), which are updated until the total number of games reaches 175,000, display final numbers. The configuration is as follows.

Further, the ratio information Rb displays the latest BB ratio in the latest 6000 game periods, but even before the total number of games reaches 6000, the latest BB for the game period of the current total number of games (<6000). Display the percentage. In the present embodiment, it is possible to specify whether the ratio information Rb displays the latest BB ratio in the game period of 6000 times or the latest BB ratio in the game period of less than 6000 times. In the above configuration, even if the ratio information Rb is inappropriate (60% or more) before the total number of games reaches 6000, if the total number of games reaches 6000, the ratio information Rb is appropriate. It is possible to recognize that there is a possibility that it will change to a different numerical value. Similarly, in the present embodiment, it is possible to specify whether the ratio information Rc displays the latest bonus ratio in the game period of 6000 times or the latest bonus ratio in the game period of less than 6000 times.

FIG. 25A is a diagram for explaining a display mode of the identification information I(a to e). In the present embodiment, it is possible to specify whether or not the number of games in the game period in which each ratio information R is calculated has reached a predetermined threshold value (175000 times or 6000 times) based on the display mode of each identification information I. did.

For example, when the total number of games is less than 17,000, the identification information Ia displayed as the ratio information Ra is displayed on the main display 40 in a display mode of “blinking” (blinking display mode), and the total number of games is 17,000. In the above case, the main display 40 is displayed in the display mode of “lighting” (lighting display mode). According to the above configuration, whether or not the ratio information Ra displays the final (175000 times game period) restricted period ratio is specified from the display mode of the identification information Ia displayed as the ratio information Ra. To be done.

Further, the identification information Id displayed as the ratio information Rd is displayed in the main display 40 in a blinking display mode when the total number of games is less than 17,000, and in the lit display mode when the total number of games is 17,000 or more. It is displayed on the display 40. According to the above configuration, whether or not the ratio information Rd displays the final BB ratio is specified from the display mode of the identification information Id displayed as the ratio information Rd. Similarly, the identification information Ie displayed as the ratio information Re is displayed in the main display 40 in a blinking display mode when the total number of games is less than 17,000, and in a lighting display mode when the total number of games is 17,000 or more. It is displayed on the main display 40. According to the above configuration, whether or not the ratio information Re displays the final bonus ratio is specified from the display mode of the identification information Ie displayed as the ratio information Re.

As shown in FIG. 25A, when the total number of games is less than 6000, the identification information Ib displayed as ratio information Rb is displayed on the main display 40 in a blinking display mode, and the total number of games is 6000 or more. In the case of, the main display 40 is displayed in a lighting display mode. According to the above configuration, whether the ratio information Rb displays the latest BB ratio of the game period of 6000 times (15 sets) or the latest BB ratio of the game period of less than 6000 times is determined by the ratio information Rb. It is specified from the display mode of the identification information Ib displayed as.

Further, the identification information Ic displayed as the ratio information Rc is displayed in the main display unit 40 in a blinking display mode when the total number of games is less than 6000, and in a lighting display mode when the total number of games is 6000 or more. It is displayed on the display 40. According to the above configuration, whether the ratio information Rc displays the latest bonus ratio of the game period of 6000 times or the latest bonus ratio of the game period of less than 6000 times is displayed as the ratio information Rc. It is specified from the display mode of the identification information Ic.

In the present embodiment, the total number of games in which each piece of identification information I changes from a lighting mode to a blinking mode is referred to as a threshold value of the identification information I. As described above, the thresholds of the identification information Ia, the identification information Id, and the identification information Ie are “175000”. The threshold value of the identification information Ib and the identification information Ic is “6000”.

FIG. 25(b-1) is a time chart for explaining a specific example of the identification information I displayed in the lighting display mode. Further, FIG. 25(b-2) is a time chart for explaining a specific example of the identification information I displayed in the blinking display mode. 25(b-1) and 25(b-2), simulated views of the first display section 40X of the main display 40 are shown. In FIG. 25(b-1) and FIG. 25(b-2), among the segs of the first display section 40X, the segs that emit light are shaded.

As shown in FIG. 25(b-1), in the lighting display mode, each light-emitting segment displaying the identification information I is maintained in a lighted state. In the specific example of FIG. 25(b-1), it is assumed that the identification information Ia (7U) is displayed. In the above specific example, each segment that emits light to represent the identification information Ia is kept in a lighted state during the period in which the identification information Ia is displayed (5 seconds before switching to other identification information I). To be done.

As shown in FIG. 25(b-2), in the blinking display mode, each lit segment that displays the identification information I blinks at a predetermined time interval. Specifically, in the blinking display mode, each light-emitting segment displaying the identification information I repeats turning on and off about every 0.6 seconds. In the specific example of FIG. 25B-2, it is assumed that the identification information Ia is displayed. In the above specific example, each segment that emits light to represent the identification information Ia repeats turning on and off about every 0.6 seconds.

As described above, in the present embodiment, the game information is updated according to the progress of the game (regulation period ratio, latest BB ratio, latest bonus ratio, BB ratio and bonus ratio), and the identification information I corresponding to the game information, Further, in the configuration including the main display 40 capable of displaying the display information H which is a combination of the ratio information R (numerical value information) indicating the size of the game information in the specific period, the display information is displayed. When the specific period is equal to or more than a predetermined number of games (6000 or 175,000), the identification information is displayed in a lighting display mode (first display mode), and the specific period is less than the predetermined number of games. , The identification information I is displayed in a blinking display mode (second display mode). According to the configuration described above, it is possible to specify whether or not the number of games in the game period in which each ratio information R is calculated has reached a predetermined threshold value by the display mode of the identification information I.

In the main RAM 303, a display permission bit storage area indicating a combination of symbols permitted to stop on the activated line, a display setting value storage area in which a numerical value displayed on the setting display unit 36 is stored, and a setting value are stored. Set value storage area, random value R1 storage area in which random value R1 is stored, random value R2 storage area in which random value R2 is stored, random value R3 storage area in which random value R3 is stored, send to sub-control board 400 Command storage area for storing commands, lamp-related data storage area for storing data indicating display states of various lamps, winning area storage area for storing winning areas, and the number of stop buttons 25 that have not been stopped. A storage area including a non-stop operation counter and a stop order storage area for storing the operation order of each stop button 25 is provided.

<Each data used by the sub CPU>
Hereinafter, various data stored in the sub ROM 413 will be described with reference to the drawings. The sub ROM 413 stores various data including an instruction effect determination table.

When receiving the second command indicating the instruction number (instruction information), the sub CPU 412 determines any of the instruction effects from the instruction effect determination table. When the instruction effect is determined, the sub CPU 412 transmits an effect control command indicating the instruction effect to the image control board (image control CPU 421) 420. When the image control CPU 421 receives the effect control command indicating the instruction effect, the image control CPU 421 causes the liquid crystal display device 30 to display each image of the instruction effect. In the present embodiment, when the sub control board (sub CPU 412) 400 receives the second command (when the main CPU 301 transmits the second command), the stop operation mode (stop operation order) corresponding to the second command is executed. The notification is always executed by the sub CPU 412.

FIG. 26 is a conceptual diagram of the instruction effect determination table. When the sub CPU 412 receives any of the commands “B01” to “B09” as the second command, the sub CPU 412 determines the instruction effect using the instruction effect determination table. As described above, the commands “B01” to “B09” are transmitted in the instruction period and not transmitted in the non-instruction period. That is, the sub CPU 412 determines the instruction effect by the instruction effect determination table in the game of the instruction period by the main CPU 301.

Specifically, in the game in which the first command “A01” is received (winning game of batting order replay), when the second command “B01” is received, the instruction effect X1 is determined. In the indication effect X1, the liquid crystal display device 30 or the like notifies the "left middle right" stop operation sequence. Further, in the game in which the first command “A01” is received, when the second command “B02” is received, the instruction effect X2 is determined, and when the second command “B03” is received, the instruction effect X3 is If determined and the second command “B04” is received, the instruction effect X4 is determined, and if the second command “B05” is received, the instruction effect X5 is determined and the second command “B06” is received. If the instruction effect X6, the instruction effect X6 is determined. In the instruction effect X2, the "right and left middle" stop order is notified, in the instruction effect X3, the "middle left and right" stop order is notified, and in the instruction effect X4, the "middle right and left" stop order is notified, and the instruction effect In X5, the "right middle left" stop order is notified, and in the instruction effect X6, the "right middle left" stop order is notified. In each of the instruction effects X (1 to 6) described above, the fact that the batting order replay is won is notified. In each of the above-described instruction effects X, the correct pressing order of the RT2 transition replay is notified.

In the game in which the first command "A01" is received, when the second command "B07" is received, the instruction effect X7 is determined. In the instruction effect X7, the liquid crystal display device 30 or the like notifies the order of the first left stop. In the game in which the first command “A01” is received, when the second command “B08” is received, the instruction effect X8 is determined, and when the second command “B09” is received, the instruction effect X9 is It is determined. In the instruction effect X8, the stop order of the middle first stop is notified, and in the instruction effect X9, the stop order of the right first stop is notified. In each of the instruction effects X (7 to 9) described above, the fact that the batting order replay is won is notified. In each of the instruction effects X described above, the correct pressing order of the RT3 transition replay is notified.

When the second command "B07" is received in the game in which the first command "A04" is received (the batting order bell winning game), the instruction effect Y1 is determined. In the instruction effect Y1, the order of the first left stop is informed by the liquid crystal display device 30 or the like. In the game in which the first command “A04” is received, when the second command “B08” is received, the instruction effect Y2 is determined, and when the second command “B09” is received, the instruction effect Y3 is determined. It is determined. In the instruction effect Y2, the stop order of the middle first stop is notified, and in the instruction effect Y3, the stop order of the right first stop is notified. In each instruction effect Y, the fact that the batting order bell has been won is notified. In each of the instruction effects Y (1 to 3) described above, the correct answer pressing order of the correct answer bell is notified.

The sub RAM 414 includes each storage area that stores each data generated and updated by the sub CPU 412 executing each process.

<Each process executed by the main CPU>
The main CPU 301 executes various processes using the above-mentioned data. FIG. 27 is a flowchart of the activation process of the main CPU 301. When the reset signal from the reset circuit is input, the main CPU 301 executes the activation process. The reset signal is output when the power supply voltage supplied to the main control board 300 exceeds a predetermined threshold value. For example, when the supply of the power supply voltage to the main control board 300 is started by turning on the power switch 511SW, the startup process is executed.

When the boot process is started, the main CPU 301 executes a boot initialization process (S1). The main CPU 301 initializes each register and the like of the main control board 300 by the initialization processing at startup. The main CPU 301 may execute a security check process for determining the validity of the control program stored in the main ROM 302 before the startup initialization process.

After the startup initialization process, the main CPU 301 determines whether the setting switch is in the ON state (S2). The setting switch is turned on when the setting key is inserted into a keyhole provided inside the gaming machine 1 and rotated. When determining that the setting switch is in the ON state (S2: YES), the main CPU 301 sets a setting change start command in the command storage area of the main RAM 303 (S3), and shifts to the setting change process.

On the other hand, when determining that the setting switch is not in the ON state (S2: NO), the main CPU 301 determines whether the backup flag is stored in the main RAM 303 (S4). In the present embodiment, when the power supply voltage supplied to the main control board 300 falls below a predetermined threshold (when the power is cut off), the main CPU 301 backs up each data stored in the main RAM 303, The backup flag is stored in the RAM 303. Therefore, if the backup is normally executed when the power is cut off, the backup flag is stored in the main RAM 303.

When determining that the backup flag is stored (S4: YES), the main CPU 301 calculates the checksum of the data stored in the main RAM 303 (S5). In the present embodiment, even when the power is cut off, the checksum of the main RAM 303 is calculated and stored, as in step S4 of the startup process.

The main CPU 301 determines whether or not the checksum calculated at step S4 (checksum at power-on) and the checksum calculated at power-off match (S6). If the data in the main RAM 303 has not changed during the period from power-off to power-on, the checksum at power-on matches the checksum at power-off. On the other hand, if the data in the main RAM 303 changes (deteriorates) during the period from when the power is turned off to when the power is turned on, the checksum at power-on does not match the checksum at power-off.

When the main CPU 301 determines that the checksum at power-on matches the checksum at power-off (S6: YES), based on each data stored in the main RAM 303, the time point when the power is cut off (backup is performed). Each register is returned to the state at the time of execution (S7). When the state of each register is restored, the main control board 300 returns to the state when the power was cut off. When the state of each register (state of the main control board 300) is restored, the main CPU 301 restarts the process from the step when the power was cut off. When returning the state of the main control board 300, the main CPU 301 transmits to the sub-control board 400 various information necessary for returning the state of the effect of the gaming machine 1.

When the main CPU 301 determines that the backup flag is not stored (S4: NO), or determines that the checksum at power-on does not match the checksum at power-off (S6: NO), A main RAM abnormality flag indicating an abnormality of the main RAM 303 is set (S8). That is, when the backup cannot be executed, or when the data in the main RAM 303 changes while the power is cut off, the main RAM abnormality flag is set. During the period when the main RAM abnormality flag is set, the main CPU 301 notifies the abnormality of the main RAM using, for example, the display ML. The main RAM abnormality flag is cleared, for example, when the setting value changing process is normally executed.

After setting the main RAM abnormality flag, the main CPU 301 shifts to RAM error processing. In the RAM error processing, the progress of the game is prohibited. In the RAM error processing, the main CPU 301 may send a command to the sub-control board 400 to notify the abnormality of the main RAM 303, and the liquid crystal display device 30 may display a warning image, for example.

FIG. 28 is a flowchart of the setting change process. When the setting change process is started, the main CPU 301 determines whether the front door 3 is open (S11). Specifically, a door sensor that outputs an OFF signal when the front door 3 is closed and outputs an ON signal when the front door 3 is open is provided, and the front door 3 is output according to the signal from the door sensor. The main CPU 301 determines whether or not is open. As described above, since the setting switch is provided inside the gaming machine 1, the setting change process is usually executed while the front door 3 is open. Therefore, as a case where the setting change process is started in the state where the front door 3 is closed, it is assumed that an ON signal of the setting switch and the power switch 511SW is input due to an illegal act. In consideration of the above circumstances, when determining that the front door 3 is not opened (S11: NO), the main CPU 301 sets the setting switch abnormality flag to the ON state (S12), and shifts to setting switch error processing. To do. In the setting switch error processing, the progress of the game is prohibited. Further, in the setting switch error processing, the main CPU 301 may be configured to send an error command to notify the abnormality of the setting switch to the sub control board 400, and the liquid crystal display device 30 may display a warning image, for example. The setting switch abnormality flag is cleared when the starting process is restarted and the setting value changing process is normally executed.

On the other hand, when determining that the front door 3 is open (S11: YES), the main CPU 301 displays a numerical value indicating the set value on the setting display unit 36 (S13). Specifically, the main CPU 301 displays the numerical value stored in the display setting value storage area of the main RAM 303 on the setting display unit 36.

After that, the main CPU 301 determines whether or not the setting change button 37 has been operated (S14). Specifically, the main CPU 301 determines whether or not the ON signal from the setting change switch 37SW is input. When determining that the setting change button 37 has been operated (S14: YES), the main CPU 301 increments the numerical value stored in the display set value storage area of the main RAM 303 (S15), and shifts the processing to step S16. On the other hand, when determining that the setting change button 37 has not been operated (S14: NO), the main CPU 301 shifts the processing to step S16 without incrementing the numerical value in the display set value storage area.

In step S16, the main CPU 301 determines whether or not the start lever 24 has been operated. Specifically, the main CPU 301 determines whether or not the ON signal of the start switch 24SW is input. The main CPU 301 repeats the processing from step S13 to step S15 until it determines that the start lever 24 has been operated (S16: NO). As understood from the above description, every time the setting change button 37 is operated and the numerical value in the display setting value storage area is added in step S15, the numerical value displayed on the setting display unit 36 is added in step S13. ..

On the other hand, when determining that the start lever 24 has been operated (S16: YES), the main CPU 301 determines the numerical value displayed on the setting display unit 36 as the set value (S17). Specifically, the main CPU 301 stores the numerical value stored in the display setting value storage area in the setting value storage area of the main RAM 303. Further, the main CPU 301 stores the set value command indicating the set value in the command storage area (S18). After storing the set value command, the main CPU 301 ends the set value changing process and shifts to the game control process. It should be noted that in the period of the startup process or the setting change process, interruption of other processing is prohibited, and when the game control processing is started, the interruption is permitted thereafter.

FIG. 29 is a flowchart of the game control process of the main CPU 301. The game control process is executed every time the player plays the game once. As will be described later in detail, the main CPU 301 executes an interrupt process at a predetermined time interval (for example, 1.49 ms) in the period in which the game control process is executed. That is, the main CPU 301 alternately executes the game control process and the interrupt process. For example, a command (for example, a start operation command described later) transmitted to the sub control board 400 is set in the game control processing and transmitted to the sub control board 400 in the interrupt processing. Also, each timer (for example, wait timer) set in the game control process is subtracted in the interrupt process.

When starting the game control process, the main CPU 301 executes an initial setting process (S101). The initial setting process is executed every time one game ends. In the initialization process, the main CPU 301 initializes a storage area of the main RAM 303 that is initialized for each game.

After the initial setting process, the main CPU 301 shifts to the automatic loading process (S102). By the automatic insertion process, the main CPU 301 sets the same number of betting medals as the previous game as the betting medals of this game when the symbol combination related to the replay is completed on the activated line as a result of the previous game.

After the automatic insertion process, the main CPU 301 shifts to the game start pre-process (S103). In the game pre-processing, the main CPU 301 detects a medal from the medal insertion unit 8 and detects an operation of the settlement button 23. Further, the main CPU 301 detects an operation of the start lever 24 (that is, a game start operation) in the game start preprocessing.

When the main CPU 301 detects a game start operation in the game start preprocessing, the main CPU 301 proceeds to the set value confirmation processing (S104). In the setting value confirmation process, the main CPU 301 determines whether the setting value stored in the setting value storage area of the main RAM 303 is appropriate. Specifically, the main CPU 301 determines whether or not the setting value stored in the setting value storage area is within the range of the numerical value “1” to the numerical value “6” in the setting value confirmation processing. When the main CPU 301 determines that the setting value is not within the range of the numerical value “1” to the numerical value “6”, the main CPU 301 stores the setting value abnormality command indicating the abnormality of the setting value in the command storage area, and shifts to the setting value error processing. .. For example, when the set value stored in the set value storage area is changed by noise, the set value error process is executed. In the setting value error process, the main CPU 301 stops the game control process (prohibits the progress of the game). When the set value error process is executed, for example, when the power button 511 is turned off and then turned on again, the main CPU 301 is caused to execute the start process and the setting change process, and a normal set value is set. , It returns to the state where the game can be played.

When determining that the set value is appropriate in the set value confirmation processing, the main CPU 301 acquires the random number value R1, the random number value R2, and the random number value R3 (S105). The random number value R1 is a hardware random number generated by the random number generator 304, and is used in the internal lottery process. The random number value R2 is a software random number acquired from a register built in the main CPU 301, and is used in the spinner effect determination process and the like. The random number value R3 is used in the AT determination process. The main CPU 301 stores the acquired random number value R1 in the random number value R1 storage area of the main RAM 303. Similarly, the main CPU 301 stores the obtained random number value R2 in the random number value R2 storage area of the main RAM 303, and stores the random number value R3 in the random number value R3 storage area of the main RAM 303.

After storing the random number value R1, the random number value R2, and the random number value R3 in the main RAM 303, the main CPU 301 proceeds to the lottery execution processing (S106). The lottery execution process is an internal lottery process for determining the winning area by the random number value R1, an AT determination process for determining the transition to the AT state by the random number value R3, and a spinning effect by the random number value R2. It is configured by each process including a rotating body effect determination process for. In addition, the lottery execution process includes an instruction number determination process for determining an instruction number.

After executing the lottery execution processing, the main CPU 301 executes wait processing (S107). The weight process is a process for making the time length of each game equal to or longer than a predetermined length. In the wait process, the main CPU 301 determines whether or not the wait period has elapsed, and when determining that the wait period has not elapsed, the main CPU 301 does not shift from the wait process to the pre-stop process described later.

On the other hand, when determining that the wait period has elapsed, the main CPU 301 proceeds to pre-stop processing (S108). In the pre-stop processing, various data (priority, etc., which will be described later) are stored in the main RAM 303 according to the winning area determined in the internal lottery processing. In the stop control process described below, each reel 12 is stopped in accordance with each data stored in the pre-stop process, so that the symbol combination related to the winning combination designated in the winning area is stopped and displayed on the activated line.

After executing the pre-stop processing, the main CPU 301 moves to the stop control processing (S109). Through the stop control process, the main CPU 301 stops the reel 12 corresponding to the stop button 25 each time the stop button 25 is operated. Each reel 12 stops at the symbol position corresponding to each data set in the above-described pre-stop processing.

When all reels 12 are stopped in the stop control process, the main CPU 301 proceeds to the display determination process (S110). In the display determination process, the main CPU 301 determines the combination of symbols displayed on the activated line. Further, the main CPU 301 sets various data according to the type of the combination of the symbols displayed on the activated line. For example, when it is determined that the symbol combination related to the replay is stopped and displayed on the activated line, the main CPU 301 sets the re-game operating flag to the ON state. When the main CPU 301 determines that the symbol combination relating to the winning combination is stopped on the activated line, the main CPU 301 adds the number of medals corresponding to the type of the winning combination to the number of credits.

After executing the display determination process, the main CPU 301 executes the state control process (S111). In the state control process, the main CPU 301 shifts the game state. In addition, in the state control process, the main CPU 301 starts or ends the regulation period with the transition of the game state. After finishing the state control process, the main CPU 301 returns the process to step S101.

FIG. 30 is a flowchart of the initial setting process. In the initial setting process, the main CPU 301 initializes the storage area of the main RAM 303 that stores information necessary for one game (S101-1). For example, the winning area storage area in which the winning area of the previous game (winning area number) is stored is initialized in the initial setting process.

After initializing the main RAM 303, the main CPU 301 determines whether the auxiliary storage unit 530 is full (S101-2). Specifically, the main CPU 301 determines whether or not the ON signal from the full tank sensor 530SE is input. When determining that the auxiliary storage unit 530 is full (S101-2: YES), the main CPU 301 sets a full tank error command (S101-3), and shifts to full tank error processing.

In the full tank error processing, the main CPU 301 notifies the full tank error using the instruction display device 16. For example, during the period in which the full-tank error process is executed, the main CPU 301 causes the instruction display device 16 to display the characters “HF” (hopper full). It should be noted that a configuration may be adopted in which the full tank error is notified by another display device (for example, the stored sheet number display device 17). When determining that the auxiliary storage unit 530 is not full (S101-2: NO), the main CPU 301 ends the game start preprocessing and shifts to the automatic insertion processing.

FIG. 31 is a flowchart of the automatic loading process. When starting the automatic insertion process, the main CPU 301 determines whether or not a symbol combination related to replay is aligned on the activated line in the previous game (S102-1). Specifically, the main CPU 301 determines whether or not the re-game operation flag is set. The re-game operation flag is set in the display determination process of the previous game control process. When the symbol combination related to the replay is not aligned in the activated line in the previous game (S102-1: NO), the main CPU 301 ends the automatic insertion process.

On the other hand, when it is determined that the symbol combination relating to the replay is aligned in the activated line in the previous game (S102-1: YES), the main CPU 301 stores the throwing command in the command storage area of the main RAM 303 (S102-). 2). After storing the closing command, the main CPU 301 sets the closing interval timer (S102-3). The closing interval timer is a timer for ensuring a time interval at which the closing command is transmitted to the sub control board 400 to be a predetermined time length or more. When the closing interval timer is set, the main CPU 301 determines whether or not the closing interval timer has timed out (S102-4). The main CPU 301 repeats step S102-4 until it determines that the closing interval timer has timed out (S102-4: NO).

When determining that the throwing interval timer has timed out (S102-4: YES), the main CPU 301 adds the numerical value “1” to the bet number counter (S102-5). The bet number counter indicates the number of bet medals in this game. Further, the main CPU 301 generates BET lamp display data indicating a display mode of the BET lamps 14 (14a, 14b, 14c) according to the value of the bet number counter (S102-6). Specifically, when the bet number counter is "1", the BET lamp display data for turning on the one-piece lamp 14a of the BET lamps 14 is generated. Similarly, when the bet number counter is "2", the BET lamp display data for turning on the one-piece lamp 14a and the two-piece lamp 14b of the BET lamp 14 is generated, and the bet number counter is "3". Generates BET lamp display data for turning on the single lamp 14a, the double lamp 14b, and the triple lamp 14c of the BET lamps 14. The BET lamp display data is stored in the lamp-related data storage area of the main RAM 303.

The main CPU 301 determines whether or not the value of the bet number counter matches the bet medal of the previous game (S102-7). The main CPU 301 repeats the processing from step S102-2 to step S102-6 until it determines that the value of the bet number counter matches the bet medal of the previous game (S102-7: NO). On the other hand, when it is determined that the value of the bet number counter matches the bet medal of the previous game (S102-7: YES), the main CPU 301 ends the automatic insertion process. As can be understood from the above description, as a result of the previous game, when the symbol combination related to the replay is aligned on the activated line, the same bet medals as the bet medals of the previous game are set in this game.

FIG. 32 is a flowchart of the game start preprocessing. When starting the game start preprocessing, the main CPU 301 refers to the game state flag in the game state storage area of the main RAM 303 to set the prescribed number (S103-1). In the present embodiment, the specified number is set to the numerical value "3" in any game.

After setting the prescribed number according to the game state, the main CPU 301 shifts to the inserted medal acceptance process (S103-2). In the inserted medal receiving process, the main CPU 301 receives medals from the medal inserting unit 8. In addition, when the main CPU 301 receives a medal from the medal insertion unit 8, the main CPU 301 adds a bet number counter or a credit number.

After executing the inserted medal acceptance process, the main CPU 301 proceeds to the BET operation acceptance process (S103-3). In the BET operation acceptance process, the main CPU 301 accepts an operation of the 1BET button 21 or an operation of the MAX-BET button 22 by the player.

After executing the BET operation reception process, the main CPU 301 proceeds to the settlement operation reception process (S103-4). The main CPU 301 receives the operation of the player's payment button 23 in the payment operation reception process.

After executing the settlement operation acceptance process, the main CPU 301 determines whether or not the bet number counter is the specified number (S103-5). When the bet number counter is added up to the specified number in the automatic insertion process of step S102, the insertion medal acceptance process of step S103-2, or the BET operation acceptance process of step S103-3, the main CPU 301 causes the bet number counter to count. Is determined to be the specified number (S103-5: YES), and the process proceeds to step S103-6. On the other hand, when the bet number counter has not reached the specified number (S103-5: NO), the main CPU 301 repeatedly executes each step from step S103-2 to step S103-4.

In step S103-6, the main CPU 301 determines whether or not the start lever 24 has been operated by the player. When determining that the start lever 24 has been operated (S103-6: YES), the main CPU 301 stores the start operation command in the command storage area of the main RAM 303 (S103-7). When the start operation command is stored, the main CPU 301 ends the game start preprocessing and shifts to the set value confirmation processing (S104). On the other hand, when determining that the start lever is not operated (S103-6: NO), the main CPU 301 repeatedly executes the steps from step S103-2 to step S103-5.

FIG. 33 is a flowchart of the inserted medal acceptance process. When the insertion medal acceptance process is started, the main CPU 301 determines whether or not the insertion impossible flag is in the ON state (S103-2-1). The thrown-disabled flag is set to an ON state in S103-2-8, which will be described later, when the bet number counter has the upper limit value and the credit amount has the upper limit value. When the main CPU 301 determines that the insertion prohibition flag is in the ON state (S103-2-1: YES), the insertion CPU accepting process ends. On the other hand, when determining that the insertion prohibition flag is not in the ON state (S103-2-1: NO), the main CPU 301 determines whether or not a medal has been inserted from the medal insertion portion 8 (S103-2-2). ).

Specifically, as described above, the medals inserted from the medal insertion unit 8 are detected by the signal from the medal sensor 34SE. In the present embodiment, the main CPU 301 reads the signal from the medal sensor 34SE in the input port reading process of the interrupt process that is periodically executed, and detects the medal in the main RAM 303 according to the signal from the medal sensor 34SE. Set the flag to the ON state. In step S103-2-2, the main CPU 301 determines whether or not the medal detection flag is in the ON state.

When determining that a medal has been inserted from the medal insertion unit 8 (S103-2-2: YES), the main CPU 301 stores an insertion command indicating that a medal has been inserted in the command storage area (S103-2-3). ).

After storing the throw-in command, the main CPU 301 determines whether or not the bet number counter is the specified number (S103-2-4). When it is determined that the bet number counter is not the specified number (S103-2-4: NO), the main CPU 301 adds the numerical value “1” to the bet number counter (S103-2-5), and the inserted medal acceptance process is performed. finish. On the other hand, when the bet number counter determines that the number is the specified number (S103-2-4: YES), the main CPU 301 adds the numerical value "1" to the credit number (S103-2-6).

After adding the number of credits, the main CPU 301 determines whether or not the number of credits matches the upper limit value “50” (S103-2-7). When it is determined that the number of credits is the numerical value “50” (S103-2-7: YES), the main CPU 301 sets the medal insertion impossible flag to the ON state (S103-2-8), and the insertion medal acceptance process is performed. finish. On the other hand, when the main CPU 301 determines that the number of credits is not the numerical value "50" (S103-2-7: NO), the inserted medal acceptance process is ended without setting the medal insertion impossible flag to the ON state. .. Note that, during the period in which the medal insertion impossible flag is set to the ON state, the main CPU 301 controls the selector 34 so that the medals inserted from the medal insertion unit 8 are guided to the outside of the gaming machine 1. Therefore, the medals inserted from the medal insertion portion 8 are ejected to the outside of the gaming machine 1 (the saucer unit 7) while the medal insertion impossible flag is in the ON state.

FIG. 34 is a flowchart of the BET operation acceptance process. In the BET operation acceptance processing, the main CPU 301 determines whether or not the number of credits is the numerical value “0” (S103-3-1). When the number of credits is the numerical value “0” (S103-3-1: YES), the main CPU 301 ends the BET operation acceptance process.

When determining that the number of credits is not “0” (S103-3-1: NO), the main CPU 301 determines whether or not the 1BET button 21 has been operated (S103-3-2). When determining that the 1-BET button 21 has been operated (S103-3-2: YES), the main CPU 301 sets a numerical value "1" to the insertion request counter (S103-3-3). On the other hand, when determining that the 1-BET button 21 has not been operated (S103-3-2: NO), the main CPU 301 determines whether or not the MAX-BET button 22 has been operated (S103-3-4). .. When determining that the MAX-BET button 22 has been operated (S103-3-4: YES), the main CPU 301 sets a numerical value "3" in the closing request counter (S103-3-5). When determining that the MAX-BET button 22 has not been operated (S103-3-4: NO), the main CPU 301 ends the BET operation acceptance process.

In step S103-3-3 or step S103-3-5, when a predetermined numerical value (numerical value “1” or numerical value “3”) is set in the closing request counter, the main CPU 301 determines from the closing request counter that the numerical value is “1”. Is subtracted (S103-3-6). When the insertion request counter is subtracted by "1", the main CPU 301 subtracts the numerical value "1" from the credit counter (S103-3-7) and adds the numerical value "1" to the bet number counter (S103-3-8). ..

After adding the numerical value “1” to the bet number counter, the main CPU 301 stores the throw-in command in the command storage area (S103-3-9). After storing the closing command, the main CPU 301 sets the closing interval timer (S103-3-10). The closing interval timer is a timer for ensuring a time interval at which the closing command is transmitted to the sub control board 400 to be a predetermined time length or more. The insertion interval timer of the BET operation acceptance processing (S103-3-10) is also used in the automatic insertion processing described above. In the BET operation acceptance process (when the MAX-BET button is operated) and the automatic closing process, the closing command is continuously output and the closing sound is continuously reproduced. In the present embodiment, since the throw-in interval timer is provided, the time interval in which each throw-in command is transmitted is ensured to be equal to or longer than the predetermined time length, and the period in which each make-up sound is output is equal to or longer than the predetermined time length. According to the above configuration, for example, the next making sound is output immediately after the outputting of the making sound of this time is started (the making sound of this time becomes extremely short), and the making sound of this time is not sensed by the player. Defects are suppressed. The closing interval timer times out, for example, in about 0.5 seconds.

The main CPU 301 determines whether or not the closing interval timer has timed out (S103-3-11). Step S103-3-11 is repeated until the closing interval timer times out (S103-3-11: NO), and when it is determined that the closing interval timer times out (S103-3-11: YES), the main CPU 301 determines It is determined whether or not the bet number counter matches the specified number (S103-3-12). When the main CPU 301 determines that the bet number counter matches the specified number (S103-3-12: YES), the BET operation acceptance process ends. On the other hand, when determining that the bet number counter does not match the specified number (S103-3-12: NO), the main CPU 301 determines whether or not the insertion request counter is the numerical value “0” (S103-3). -13). When determining that the insertion request counter is the numerical value “0” (S103-3-13: YES), the main CPU 301 ends the BET operation acceptance process. On the other hand, when determining that the input request counter is not the numerical value “0” (S103-3-13: NO), the main CPU 301 determines whether or not the credit amount is “0” (S103-3-14). ). When the main CPU 301 determines that the number of credits is “0” (S103-3-14: YES), it ends the BET operation acceptance process and determines that the credit counter is not “0” (S103-3). -14: NO), and returns the processing to step S103-3-6.

As can be understood from the above description, when the main CPU 301 accepts the operation of the MAX-BET button 22, the bet number counter is incremented until the bet number counter reaches the specified number or the credit amount is exhausted.

FIG. 35 is a flowchart of the settlement operation acceptance process. In the settlement operation acceptance process, the main CPU 301 determines whether or not the settlement button 23 is operated by the player (S103-4-1). When determining that the settlement button 23 has been operated (S103-4-1: YES), the main CPU 301 sets a settlement medal in the payout request counter (S103-4-2). The settlement medal is the total of the bet number counter and the credit number at the time when the settlement button 23 is operated. However, when the bet number counter is added by automatic insertion (when the replay is stopped in the previous game), the main CPU 301 sets only the credit amount in the payout request counter. With the above configuration, the settlement of the betting medals set by automatic insertion is prohibited. After setting the settlement medal in the payout request counter, the main CPU 301 stores a settlement operation command indicating the operation of the settlement button 23 in the command storage area of the main RAM 303 (S103-4-3), and sets the medal insertion impossible flag to the OFF state. (S103-4-4).

When it is determined that the settlement button 23 is not operated (S103-4-1: NO), the main CPU 301 ends the settlement operation acceptance process. As will be described later in detail, in the hopper drive process, the number of medals of the payout request counter is discharged from the hopper 520 to the tray unit 7 via the medal payout outlet 9.

FIG. 36 is a flowchart of the lottery execution processing. When starting the lottery execution process, the main CPU 301 executes the internal lottery process (S106-1). In the internal lottery process, the main CPU 301 determines the winning area for the current game from the random number value R1. After executing the internal lottery process, the main CPU 301 shifts to the spinning drum effect determination process (S106-2). In the spinner effect determination process, the main CPU 301 determines the spinner effect for the current game from the random number value R2. After executing the spinning effect determination process, the main CPU 301 proceeds to the AT determination process (S106-3).

In the AT determination process, the main CPU 301 determines from the random number value R3 whether to shift to the AT state. Specifically, in the AT determination process, the main CPU 301 obtains a lottery value corresponding to the winning area of this game and the spinning drum effect from the AT determination table, and subtracts the lottery value from the random number value R3. In the normal state, when the result of subtracting the lottery value to the random number value R3 becomes a negative number, the main CPU 301 sets the initial value in the precursor counter. As described above, the omen counter indicates the number of remaining games in the omen state, and the initial values of the numerical values “0” to “32” are set. The initial value of the precursor counter is determined by lottery. In the present embodiment, in the AT determination process in the AT state, the addition determination process is executed. In the addition determination process, the number of addition games is determined according to the winning area. After executing the AT determination process, the main CPU 301 shifts to the chance state determination process (S106-4).

In the chance state determination process, the main CPU 301 determines from the random number value R3 whether or not to shift to the chance state. Specifically, in the chance state determination process, the main CPU 301 obtains a lottery value corresponding to the winning area of this game and the spinning effect from the chance state determination table, and subtracts the lottery value from the random number value R3. .. In the normal state, when the result of subtracting the lottery value to the random number value R3 becomes a negative number, the main CPU 301 sets the initial value in the precursor counter. As described above, the omen counter indicates the number of remaining games in the omen state, and the initial values of the numerical values “0” to “32” are set. The initial value of the precursor counter is determined by lottery.

After executing the chance state determination process, the main CPU 301 shifts to the special state determination process (S106-5). In the special state determination process, the main CPU 301 executes the special state determination process of determining whether or not to shift to the special state (first special state, second special state), and then the main CPU 301 determines the instruction number determination process ( Then, the process proceeds to S106-6).

FIG. 37 is a flowchart of the internal lottery process. When starting the internal lottery process, the main CPU 301 sets a winning area lottery table according to the gaming state (S106-1-1). For example, the main CPU 301 sets the winning area lottery table in accordance with the RT flag indicating the type of RT state stored in the RT state storage area of the main RAM 303.

In the internal lottery process, the main CPU 301 acquires the random number value R1 stored in the random number value R1 storage area (S106-1-2). The random number value R1 is stored in the random number value R1 storage area in step 105. In addition, the main CPU 301 sets the winning area offset value to the initial value “00” (S106-1-3). The winning area offset value specifies each winning area. The winning area offset value is sequentially updated, and a different winning area is designated each time it is updated. For example, the winning area offset value is a numerical value of "00", and designates the winning area of "miss".

The main CPU 301 acquires the lottery value of the winning area designated by the winning area offset value (S106-1-4). For example, when the winning area lottery table in the RT0 state is set, if the winning area offset value is the numerical value “00”, the lottery value “37042” is acquired.

The main CPU 301 subtracts the lottery value acquired in step S106-1-4 from the random number value R1 acquired in step S106-1-1 (S106-1-5). Further, the main CPU 301 determines whether or not the result of subtracting the lottery value from the random number value R1 is a negative number (S106-1-6). For example, in the game in the RT0 state, when a random number value R1 smaller than the numerical value “37042” is acquired, the result of subtracting the lottery value “37042” of the winning area number “00” from the random number value R1 becomes a negative number. On the other hand, when a random number value R1 larger than the numerical value “37042” is acquired, the result of subtracting the lottery value of the winning area number “00” from the random number value R1 is not a negative number.

When the main CPU 301 determines that the subtraction result is not a negative number (S106-1-6: NO), whether or not all winning areas (winning area numbers “00” to “32”) are designated by the winning area offset value. It is determined (S106-1-7). When all the winning areas have not been designated (S106-1-7: NO), the main CPU 301 updates the winning area offset value (adds a numerical value "1") (S106-1-8), and step S106-. Return the process to 1-4. In step S106-4, the lottery value of the winning area designated by the updated winning area offset value is acquired, and in step S106-1-5, the lottery value is subtracted from the previous subtraction result. The processing from step S106-1-4 to step S106-1-8 is performed until it is determined that the calculation result is a negative number (S106-1-6: YES) or all winning areas are designated (S106- 1-7: YES) Repeated.

When it is determined that the calculation result is a negative number or when all the winning areas are designated, the main CPU 301 executes a data storage process (S106-1-9). Specifically, the main CPU 301 stores the current winning area offset value in the winning area storage area of the main RAM 303. For example, when the winning area offset value whose subtraction result is a negative number is "12", the numerical value "12" is stored in the winning area storage area. In the data storage process, the main CPU 301 stores the first command corresponding to the winning area in the command storage area of the main RAM 303. The main CPU 301 transmits the first command stored in the command storage area to the sub control board 400 in the command transmission process of the interrupt process described later.

FIG. 38 is a flowchart of the instruction number determination process. When the instruction number determination process is started, the main CPU 301 determines whether or not the current game is in the instruction period (S106-5-1). When determining that it is the instruction period (S106-5-1: YES), the main CPU 301 determines the instruction number using the instruction determination table A (S106-5-2). On the other hand, when determining that it is not the instruction period (S106-5-1: NO), the main CPU 301 determines the instruction number using the instruction determination table B (S106-5-3). As described above, the instruction number “99” (no instruction) is determined in all the winning areas in the non-instruction period.

After determining the instruction number in step S106-5-2 or step S106-5-3, the main CPU 301 stores the instruction number in the instruction number storage area. The instruction number storage area is stored in, for example, the main RAM 303. The main CPU 301 causes the instruction display unit 16 to display the instruction information corresponding to the instruction number stored in the instruction number storage area in the LED display processing of the interrupt processing described later. Further, the main CPU 301 transmits the second command indicating the instruction number stored in the instruction number storage area in the command transmission process of the interrupt process. After storing the instruction number, the main CPU 301 ends the instruction number determination process.

FIG. 39 is a flowchart of the wait process. The main CPU 301 executes a wait process until the execution period of the spinning drum effect or the wait period elapses.

When the wait process is started, the main CPU 301 determines whether or not the spinning effect number in the spinning effect number storage area is "0" (S107-1). That is, it is determined whether or not "no effect" is determined in the spinner effect determination process. When the spinning effect number is "0" (S107-1: YES), the main CPU 301 determines whether the wait timer is a numerical value "0" (S107-2). The wait timer is decremented each time the interrupt processing is executed. When determining that the wait timer has not timed out (wait timer≠0), the main CPU 301 repeats step S107-2 (S107-2: NO).

On the other hand, when determining that the wait timer has timed out (S107-2: YES), the main CPU 301 newly sets the wait timer to the initial value (about 4100 ms) (S107-3). Further, the main CPU 301 stores a reel start command indicating that each reel 12 has started in the command storage area of the main RAM 303 (S107-4), starts rotation of each reel 12, and ends the wait process.

When the main CPU 301 determines in step S107-1 that the rotating body effect number is other than "0", the rotating body effect number indicates "1" indicating the rotating body effect A, or "indicating the rotating body effect B". It is determined whether it is "2" (S107-5). When it is determined that the spinning effect number is "1" or "2" (S107-5: YES), the main CPU 301 sets the spinning effect timer to 1000 sm (S107-6).

On the other hand, when it is determined that the rotating body effect number is not "1" or "2" (S107-5: NO), the main CPU 301 determines whether the rotating body effect number is "3" indicating the rotating body effect C. It is determined whether or not (S107-7). When determining that the spinning effect number is "3" (S107-7: YES), the main CPU 301 sets 2000 sm to the spinning effect timer (S107-8). On the other hand, when it is determined that the rotating body effect number is not “3” (S107-7: NO), that is, when the rotating body effect number is “4” indicating the rotating body effect D, the main CPU 301 causes the main body CPU 301 to rotate the body. The effect timer is set to 5000 sm (S107-9).

When the main body CPU 301 sets the rotating body effect timer in steps S107-6, S107-8, and S107-9, the main CPU 301 determines whether or not the rotating body effect timer has been decremented to the value "0" (S107-10). .. The rotating body effect timer is decremented each time the interrupt process is executed. When the main CPU 301 repeats step S107-10 (S107-10: NO) until the spinning effect timer expires (that is, until the spinning effect ends), and determines that the spinning effect timer has expired. (S107-10: YES), the process proceeds to step S107-2.

FIG. 40 is a flowchart of the pre-stop processing. When starting the pre-stop processing, the main CPU 301 sets an initial value in the acceleration wait timer (S108-1). The initial value of the acceleration wait timer is set to the length of time required for each reel 12 to accelerate from the start to the steady rotation. After setting the initial value in the acceleration wait timer, the main CPU 301 determines whether or not the acceleration wait timer has timed out (S108-2). The main CPU 301 repeats step S108-2 until the acceleration wait timer times out (S108-2: NO), and when the acceleration wait timer times out (S108-2: YES), shifts the processing to step S108-3. To do.

In step S108-3, the main CPU 301 stores the numerical value “3” in the unstopped operation counter indicating the number of the stop buttons 25 (25L, 25C, 25R) that have not been stopped. Further, the main CPU 301 performs a display combination storing area setting process (S108-4). As described above, each displayable bit in the display combination storing area corresponds to each winning combination, and is a numerical value “1” when the symbol combination related to the corresponding winning combination may stop on the activated line. Therefore, in step S108-4 in which all reels 12 are rotating, since all the symbol combinations related to the winning combination can be stopped on the activated line, all the bits of the display combination storing area are set to the numerical value "1". Is set.

After the display combination storing area setting process, the main CPU 301 shifts to the priority order storing process (S108-5). FIG. 41 is a conceptual diagram of a plurality of priority order storage areas P (PL, PC, PR) set in the priority order storage process. As shown in FIG. 41, the priority storage area P includes a left reel priority storage area PL corresponding to the reel 12L, a middle reel priority storage area PC corresponding to the reel 12C, and a right reel priority storage corresponding to the reel 12R. The ranking storage area PR is included. Also, each priority storage area P is divided into a plurality (21) of areas Q. Each area Q corresponds to each symbol position (unit area U) of the reel 12.

When the priority storage process is executed, the priority of the symbols in the area Q is stored in each area Q. For example, when the player stops on the activated line, the priority order “HFF” is stored in the area Q in which the winning combination that has not been won is displayed. Further, a priority "H00" is stored in the area Q of the symbol that can be stopped on the activated line, and a numerical value "H01" is stored in the area Q of the symbol which constitutes the winning combination.

FIG. 42 is a flowchart of the priority order storing process. When starting the priority storage process, the main CPU 301 stores the unstopped operation counter as the number of searches (S108-5-1). Further, the main CPU 301 determines one of the reels 12 which has not been stopped yet as a target reel (S108-5-2).

The main CPU 301 executes a priority table selection process (S108-5-3). The priority table defines the priority of each winning combination, and one of the plurality of priority tables is selected. For example, assume a game in which the winning area “bat order bells R1 to R4” (the first stop in the correct pressing order is the reel 12R) is won. According to the priority table selected in the game, in the right reel priority storage area PR, the priority of the "correct answer bell" symbol is higher than the priority of the "upper bell" symbol. On the other hand, in the left reel priority storage area PL and the middle reel priority storage area PC, the priority of the "upper bell" symbol is higher than the priority of the "correct answer bell" symbol. According to the above configuration, by appropriately selecting the priority order table, the symbol stopped on the activated line changes according to the stop operation order.

After executing the priority table selection process, the main CPU 301 stores the initial value “00” in the area pointer and the initial value “21” in the remaining area number (S108-5-4). The area pointer designates the area Q of the target reel. The remaining number of areas means the number of areas Q in which priority is not stored in the target reel.

The main CPU 301 acquires the symbol code (symbol type) at the symbol position designated by the area pointer (S108-5-5). Further, the main CPU 301 determines the priority order according to the symbol code, the winning area (winning combination), and the priority order table (S108-5-6). The main CPU 301 stores the determined priority in the area Q designated by the current area pointer (S108-5-7).

The main CPU 301 adds the numerical value "1" to the area pointer and subtracts the numerical value "1" from the remaining area number (S108-5-8). After that, the main CPU 301 determines whether or not the remaining area number is a numerical value “0” (S108-5-9). When determining that the number of remaining areas is not “0” (S108-5-9: NO), the main CPU 301 repeatedly executes steps S108-5-5 to S108-5-9. On the other hand, when it is determined that the remaining number of areas is “0” (S108-5-9: YES), that is, when the generation of the priority storage area of the target reel is completed, the main CPU 301 determines “ 1” is subtracted (S108-5-10).

After subtracting the search count, the main CPU 301 determines whether or not the search count has ended (S108-5-11). When determining that the number of searches has not ended (S108-5-11: NO), the main CPU 301 returns the process to step S108-5-2, changes the target reel, and then steps from step S108-5-2. The steps up to S108-5-11 are repeatedly executed. On the other hand, when determining that the number of searches has been completed (S108-5-11: YES), the main CPU 301 ends the priority storage process.

FIG. 43 is a flowchart of the stop control process. The main CPU 301 determines whether or not the stop button 25 corresponding to the spinning reel 12 has been operated (S109-1). The main CPU 301 repeatedly executes step S109-1 until the stop button 25 corresponding to the spinning reel 12 is operated (S109-1: NO). On the other hand, when the stop button 25 corresponding to the spinning reel 12 is operated (S109-1: YES), the main CPU 301 issues a stop operation command indicating the type of the stop button 25 that has been stopped to the command of the main RAM 303. The data is stored in the storage area (S109-2).

When the stop operation command is stored, the main CPU 301 updates the stop order storage area (S109-3). Further, the main CPU 301 subtracts the numerical value “1” from the unstopped operation counter (S109-4). The main CPU 301 sets the reel 12 corresponding to the operated stop button 25 as the stop target reel (S109-5).

The main CPU 301 acquires the current value of the symbol counter (that is, the symbol number located on the middle line) as the stop operation position (S109-6). Of the areas Q of the priority order storage area of the target reel, the main CPU 301 determines the priority order of the area Q at the stop operation position and the area Q of four frames from the frame next to the stop operation position (that is, five frames). (Priority order of) is acquired (S109-7). Further, the main CPU 301 determines the highest priority frame among the acquired priorities of the five frames as the planned stop position, and sets the number of frames from the stop operation position to the planned stop position as the number of sliding frames ( S109-8).

The main CPU 301 updates each bit of the display combination storing area according to the symbol code of the planned stop position (that is, the type of the symbol of the planned stop position) (S109-9). For example, when the reel 12L is stopped and the symbol "bell" is stopped on the activated line in the stop control process, the symbol combination related to the winning combination (for example, the cherry combination) in which the symbol of the left reel is not "bell" is on the activated line. Since there is no possibility of stopping, the bit corresponding to the winning combination among the respective bits of the display combination storing area becomes the numerical value “0”.

After updating the display combination storing area, the main CPU 301 determines whether or not the unstopped operation counter is “0” (S109-10). The numerical value “0” of the non-stop operation counter means that the stop operation has been performed for all reels 12. When determining that the unstopped operation counter is “0” (S109-10: YES), the main CPU 301 ends the stop control process. On the other hand, when it is determined that the unstopped operation counter is not "0" (S109-10: NO), the priority order storing process executed in the pre-stop process is executed (S109-11). In step S109-11, the priority is stored in the priority storage area P of the spinning reel 12 as in step S109-3 of the pre-stop processing. However, even if the symbols constituting the winning combination shown in the winning area of the winning area storage area, there is no possibility of being displayed on the activated line because one of the reels 12 is stopped. The symbol is not set to have a higher priority than other symbols.

After executing the priority order storing process, the main CPU 301 returns the process to step S109-1. The main CPU 301 repeats the processing from step S109-1 to step 109-11 until a stop operation is performed on all reels 12, that is, until it is determined that the unstopped operation counter is “0”. Run. When it is determined that the unstopped operation counter is “0” (S109-10: YES), the main CPU 301 ends the reel stop control process.

FIG. 44 is a flowchart of the display determination process (S110). When the display determination process is started, the main CPU 301 determines whether or not the symbol combination related to the winning combination stopped on the activated line is the symbol combination related to the winning combination permitted to be stopped on the activated line in the game. (S110-1). Specifically, in step S110-1, the main CPU 301, for the winning combination corresponding to the displayable bit set to "1" among the displayable bits in the display combination storing area, the display permission corresponding to the winning combination. Determine if the bit is set to "1". When the display permission bit corresponding to the displayable bit of the numerical value “1” is set to “0”, the main CPU 301 determines that an unauthorized winning has occurred.

When the main CPU 301 determines that the illegal prize has been generated (S110-1: YES), it stores the illegal prize command in the command storage area of the main RAM 303 (S110-2), and shifts to the illegal prize error processing to play the game. Prohibit progress. When the illegal prize winning error process is executed, for example, the power button 511 is turned off and then turned on again, and the main CPU 301 is caused to execute the startup process and the setting change process to set a normal setting value. Now you can play.

When it is determined that the symbol combination related to the winning combination which is permitted to stop on the activated line is stopped (S110-1: NO), the main CPU 301 determines whether or not the symbol combination related to replay is stopped on the activated line. The determination is made (S110-3). When it is determined that the symbol combination effective line related to the replay is stopped (S110-3: YES), the main CPU 301 sets the regame operation flag to the ON state (S110-4), and the replay command is issued. The data is stored in the command storage area of the main RAM 303 (S110-5), and the display determination process ends. The replay command indicates that the symbol combination related to the replay has stopped on the activated line.

On the other hand, when it is determined that the symbol combination relating to the replay is not stopped on the activated line (S110-3: NO), the main CPU 301 sets the re-game operation flag to the OFF state (S110-6), and wins the prize. It is determined whether or not the symbol combination related to the winning combination is stopped on the activated line (S110-7). When it is determined that the symbol combination related to the winning combination is stopped on the activated line (S110-7: YES), the main CPU 301 stores the winning combination command in the command storage area of the main RAM 303 (S110-8). .. The winning combination command indicates the type of symbol combination related to the winning combination arranged on the activated line.

The main CPU 301 adds to the number of credits the number of medals according to the type of symbol combination related to the winning winning combination stopped on the activated line (S110-9). After adding the credit number, the main CPU 301 determines whether or not the added result is larger than the numerical value “50” which is the upper limit value of the credit number (S110-10). When the number of credits is larger than “50” (S110-10: YES), the number of medals that exceeds the upper limit of the number of credits (for example, when the addition result of step S110-9 is “55”, the numerical value is “5”). ") is set in the medal request counter (S110-11). After setting the number of medals in the medal request counter, the main CPU 301 shifts to the hopper drive processing. On the other hand, when the number of credits is “50” or less (S110-10: NO), the main CPU 301 ends the display determination process.

When the main CPU 301 determines in step S110-7 that the symbol combination related to the winning combination is not stopped on the activated line (S110-7: NO), the symbol combination related to the bonus combination is stopped and displayed on the activated line. It is determined whether or not (S110-12). When determining that the symbol combination related to the bonus combination is stopped and displayed on the activated line (S110-12: YES), the main CPU 301 stores the bonus combination command in the command storage area of the main RAM 303 (S110-13). The bonus combination command indicates that the symbol combination related to the bonus combination is stopped and displayed on the activated line. The main CPU 301 ends the display determination process after storing the bonus combination command.

When determining in step S110-12 that the symbol combination related to the bonus combination is not stopped on the activated line (S110-12: NO), the main CPU 301 stores the lost display command in the command storage area of the main RAM 303 ( S110-14). The lose display command indicates that the symbol combination related to the winning combination is not stopped on the activated line. In the present embodiment, the re-play command, the winning combination command, the lost display command, and the bonus combination command are collectively referred to as the display winning combination command.

FIG. 45 is a flowchart of the hopper drive processing. The hopper drive processing is executed when the payout request counter is set in the display determination processing or the settlement operation acceptance processing of the game start preprocessing. When the hopper drive processing is started, the main CPU 301 stores the payout start command in the command storage area of the main RAM 303 (S120). The payout start command indicates the start of medal discharge in the hopper 520. Further, the main CPU 301 sets an initial value in the payout period monitoring timer (S121). The payout period monitoring timer is timed up when a predetermined time length (for example, 30 seconds) has elapsed since the hopper drive processing was started.

The main CPU 301 starts output of the hopper drive signal (S122). Medals are sequentially discharged from the hopper 520 during the period in which the hopper drive signal is output. After starting the output of the hopper drive signal, the main CPU 301 determines whether or not the payout period monitoring timer has timed out (S123). When determining that the payout period monitoring timer has timed out (S123: YES), the main CPU 301 stores the error command in the command storage area (S124), and shifts to the hopper empty error processing. In the above-described configuration, the main CPU 301 shifts to the hopper empty error process when the ejection of the number of medals of the payout request counter is not completed from the start of the hopper drive process to the expiration of the payout period monitoring timer. Prohibit the progress of the game. When the hopper empty error process is executed, the process returns to the hopper drive process, for example, on condition that the reset button 512 is operated.

The main CPU 301 determines whether or not the payout signal from the hopper 520 has been detected (S125). As described above, the payout signal is output from the payout sensor 112SE every time one medal is paid out from the hopper 520. The main CPU 301 repeatedly executes step S123 and step S125 until it determines that the payout signal is detected (S125: NO).

When determining that the payout signal is detected (S125: YES), the main CPU 301 subtracts the numerical value “1” from the payout request counter (S126). After that, the main CPU 301 determines whether or not the payout request counter has been decremented to the numerical value “0” (S127). When determining that the payout request counter has been decremented to the value “0” (S127: YES), the main CPU 301 stops the output of the hopper drive signal (S128) and stores the payout end command in the command storage area of the main RAM 303. (S129). For example, the sub-control board 400 starts outputting the payout sound effect when receiving the payout start command from the main CPU 301, and stops outputting the payout sound effect when receiving the payout end command. When the main CPU 301 stores the payout end command, the main CPU 301 ends the hopper drive process. On the other hand, when determining that the payout request counter is not "0" (S127: NO), the main CPU 301 repeatedly executes steps S123 to 127.

FIG. 46A is a flowchart of the state control process. When the state control process is started, the main CPU 301 executes the RT state transition process (S111-1). In the RT state shift processing, the main CPU 301 shifts the RT state. Specifically, the main CPU 301 determines whether or not the RT1 transition symbol has stopped on the activated line in the RT state transition process. As described above, the RT1 transition symbol stops on the effective line when the failure bell is missed. When the main CPU 301 determines that the RT1 shift symbol has stopped on the activated line, the main CPU 301 shifts to the RT1 state. In addition, in the RT1 state, when the RT1 transition symbol stops on the activated line, the RT state is not changed. Further, the main CPU 301 determines whether or not the RT2 transition symbol has stopped on the activated line in the RT state transition processing. When determining that the RT2 transition symbol has stopped on the activated line, the main CPU 301 changes the RT state to the RT2 state. Further, the main CPU 301 determines whether or not the ending condition of the bonus operation state is satisfied in the current game in the RT state transition process. When determining that the condition for ending the bonus operation state is satisfied, the main CPU 301 changes the RT state to the RT0 state.

After the RT state transition process, the main CPU 301 executes a game state transition process (S111-2). The main CPU 301 shifts each game state in the game state shift processing according to the game state of the current game. Specifically, when the main CPU 301 wins the AT state in the current game, the main CPU 301 shifts to the start preparation state or the precursor state according to the number of times of the precursor state game. As described above, the number of games in the omen state is determined by a lottery from any of the numerical values “0” to “32”. When the number of games in the omen state determined when the AT state is won is “0”, the game state shifts to the start preparation state. Also, when the number of games in the omen state is greater than the numerical value “0”, the game state shifts to the omen state. The number of games in the omen state determined by lottery is stored in the omen counter, and the omen counter is subtracted for each game in the omen state. When the precursor counter is decremented to the value “0”, the state shifts to the AT state.

When the main CPU 301 wins the chance state in the normal state game, it shifts to the chance state or the precursor state according to the number of times of the precursor state game. As described above, for the number of games in the omen state, any one of the numerical values “0” to “32” is determined by lottery. When the number of games in the omen state determined when the player wins the chance state is “0”, the game state shifts to the chance state. Also, when the number of games in the omen state is greater than the numerical value “0”, the game state shifts to the omen state. The number of games in the omen state determined by lottery is stored in the omen counter, and the omen counter is subtracted for each game in the omen state. When the precursor counter is decremented to the value "0", the state shifts to the chance state. When shifting to the chance state, the main CPU 301 stores the initial value “10” in the chance state counter.

The main CPU 301 subtracts the numerical value "1" from the chance state counter in each game in the chance state. Further, in the game state transition processing, the main CPU 301 determines whether or not the chance state counter has been decremented to the numerical value “0”. If it is determined that the chance state counter has been decremented to the numerical value “0” and if the AT state is won in the present chance state, then the state shifts to the start preparation state. On the other hand, if the player has not won the AT state in this chance state, the game state is shifted depending on whether or not the right to shift to the next chance state is granted. Specifically, if the right to shift to the next chance state is granted, the main CPU 301 shifts to the chance state, and if the right to shift to the next chance state is not granted, shifts to the normal state. ..

The main CPU 301 determines whether or not the game has transitioned to the RT2 state in each game in the start preparation state. Specifically, the main CPU 301 determines in the game state transition processing whether or not the RT state has transitioned to the RT2 state in the RT state transition processing of the current game. When it is determined that the game state has shifted to the RT2 state, the game state shifts to the AT state, and when it is determined that the game state has not shifted to the RT2 state, the start preparation state is continued.

The main CPU 301 decrements the AT counter by a numerical value “1” in each game in the AT state. Further, in the game state transition processing, the main CPU 301 determines whether or not the AT counter has been decremented to the numerical value “0”. When the main CPU 301 determines that the AT counter has been decremented to the value “0”, the main CPU 301 shifts to a termination preparation state. In each game in the end preparation state, it is determined whether or not the state has transitioned to the RT1 state, and when it is determined that the state has transitioned to the RT1 state, the state returns from the end preparation state to the normal state.

In the game state transition process of each game, the main CPU 301 determines whether or not a bonus combination has been won in this game. Further, the main CPU 301 determines whether or not the symbol combination related to the bonus combination is stopped and displayed on the activated line in this game. When it is determined that the bonus combination is won in the game this time and it is not determined that the symbol combination related to the bonus combination is stopped and displayed on the activated line, the main CPU 301 shifts to the internal state.

When determining that the combination related to the bonus combination is stopped and displayed on the activated line in this game, the main CPU 301 shifts the game state to the bonus operation state. In the bonus operation state, the main CPU 301 counts the number of paid out medals and determines whether or not the number of medals exceeds the numerical value “297”. When determining that the number of medals exceeds the numerical value “297”, the main CPU 301 ends the bonus operation state.

When the bonus operation state ends, the main CPU 301 shifts to the gaming state in which the bonus combination is won. For example, when the bonus combination is won in the normal state, the normal state is entered after the bonus operation state ends, and when the bonus combination is won in the AT state, the bonus state is entered and then the AT state is entered. However, even if the bonus combination is won in the AT state, the main CPU 301 shifts to the normal state if the regulation period ends at the time when the bonus operation state ends.

FIG. 46B is a flowchart of the regulation period shift processing. The regulation period shift processing is executed in the state control processing of each game. Note that the regulation period transition process may be configured to be executed by a process other than the state control process.

As shown in FIG. 46(b), when the restriction period shift processing is started, the main CPU 301 determines whether or not the restriction period flag is in the OFF state (S501). The regulation period flag is maintained in the ON state in each gaming state (AT state or the like) in the regulation period, and is maintained in the OFF state in each gaming state (normal state or the like) other than the regulation period. The regulation period flag is provided in the main RAM 303, for example.

When determining that the restriction period flag is in the OFF state (S501: YES), the main CPU 301 determines whether or not the game has transitioned to the omen state in this game (S502). When it is determined that the game has transitioned to the omen state (S502: YES), the main CPU 301 sets the regulation period flag to the ON state (S503) and ends the regulation period transition process. In the above configuration, the right to shift to the AT state or the chance state is given in the normal state, and when the shift to the precursor state is made, the regulation period flag is turned on.

When determining that the current game has not transitioned to the omen state (S502: NO), the main CPU 301 determines whether the current game has transitioned to the start preparation state (S504). When it is determined that the game has transitioned to the start preparation state (S504: YES), the main CPU 301 sets the regulation period flag to the ON state (S503), and ends the regulation period transition process. In the above configuration, when the right to shift to the AT state is granted and then the shift to the start preparation state is performed without going through the precursory state, the regulation period flag is turned on.

When it is determined that the current game has not transitioned to the start preparation state (S504: NO), the main CPU 301 determines whether the current game has transitioned to the chance state (S505). When it is determined that the game has transitioned to the chance state (S505: YES), the main CPU 301 turns on the regulation period flag (S503) and ends the regulation period transition processing. In the above configuration, the right to shift to the chance state is granted, and then, if the state shifts to the chance state without going through the precursory state, the regulation period flag is turned on.

When it is determined in step S501 that the restriction period flag is not in the OFF state, it is determined whether or not the game has transitioned to the normal state or the end preparation state in this game (S506). For example, if the AT state ends in this game and shifts to the end preparation state, or if the chance state ends in this game and shifts to the normal state, YES is determined in step S506. When it is determined that the game has transitioned to the normal state or the end preparation state in this game, the main CPU 301 changes the restriction period flag to the OFF state (S507) and executes the initialization process (S508). In the initialization process when the restriction period ends, as described above, various counters such as the restriction counter are initialized. After completing the initialization process, the main CPU 301 proceeds to step S512.

When it is determined that the current game has not transitioned to the normal state (S506: NO), the main CPU 301 determines whether or not the regulation counter has been added to the numerical value “1500” or more (S509). As a case where the determination of YES is made in step S509 described above, for example, it is assumed that the bonus combination is won in the AT state, and the regulation counter is added to the numerical value “1500” in the subsequent bonus operation state. When it is determined that the restriction counter is 1500 or more (S509: YES), the main CPU 301 sets the restriction period flag to the OFF state, as in the case where it is determined that the game has transitioned to the normal state or the end preparation state. It is changed (S507) and the initialization process (S508) is executed.

When determining that the regulation counter is not equal to or greater than the numerical value "1500" (S509: NO), the main CPU 301 adds the numerical value "1" to the regulation counter (S510) and also adds the numerical value "1" to the total regulation period counter. Yes (S511). As described above, the total restriction period counter is used to display the ratio information indicating the restriction period ratio, and is added in each game of the restriction period. After adding the total restriction period counter, the main CPU 301 proceeds to step S512. In step S512 of the restriction period control process, the main CPU 301 adds the numerical value “1” to the total game number counter. As described above, the total game number counter is used to display the ratio information indicating the restriction period ratio, and is added in each game. After adding the total game number counter, the main CPU 301 shifts to the display control process (S513).

In the display control process, the main CPU 301 turns on or off the regulation period display 38. Specifically, in step S503 described above, when the restriction period flag is changed to the ON state, the main CPU 301 turns on the restriction period display 38 in the display control process. Further, when the restriction period flag is changed to the OFF state in step S507 described above, the main CPU 301 turns off the restriction period indicator 38 in the indicator control process. After executing the display device control process, the main CPU 301 ends the restriction period shift process.

FIG. 47 is a flowchart of the interrupt process. As described above, the main CPU 301 executes the interrupt process every 1.49 ms during the period of executing the game control process.

When starting the interrupt processing, the main CPU 301 saves data in various registers (S201). After that, the main CPU 301 executes an input port reading process (S202). In the input port reading process, the main CPU 301 reads various signals input to the I/F circuit 305. Specifically, the main CPU 301 reads ON signals of the start switch 24SW, each stop switch 25SW, the medal sensor 34SE, the settlement switch 23SW, etc. in the input port reading process. The main CPU 301 sets the detection flags of the sensor and switch that read the ON signal to the ON state.

The main CPU 301 executes a timer measurement process (S203). In the timer measurement process, the main CPU 301 subtracts a predetermined value from various timers. In the timer measurement process, the main CPU 301 subtracts, for example, the payout period monitoring timer set in the hopper drive process, the turning drum effect timer and the wait timer set in the wait process.

The main CPU 301 selects a drive target reel from the rotating reels (S204) and executes drive control processing for the drive target reel (S205). In the drive control process, the main CPU 301 outputs a drive pulse to the stepping motor of the reel to be driven. When the drive pulse is input, the excitation pattern of the stepping motor is switched.

The main CPU 301 determines whether the drive control processing for all reels 12 has been executed (S206). When determining that the drive control processing for all reels 12 has not been executed (S206: NO), the main CPU 301 repeats steps S204 and S205. On the other hand, when it is determined that the drive control processing for all reels 12 has been executed (S206: YES), the main CPU 301 shifts to external signal output processing (S207).

The main CPU 301 outputs a predetermined signal to the outside of the gaming machine 1 in the external signal output process. For example, when the setting change process is started, the main CPU 301 outputs a signal indicating the start of the setting change process to the outside of the gaming machine 1.

The main CPU 301 drives various lamps in the LED display process (S208). For example, the main CPU 301 displays the BET lamp 14 in the mode indicated by the BET lamp display data generated in the game control process. Further, in the LED display process, the main CPU 301 lights the re-game display lamp 18 when the re-game operating flag is set to the ON state. In addition, the main CPU 301 causes the accumulated number display unit 17 to display the number of credits in the LED display process. Further, in the LED display processing, the main CPU 301 causes the instruction display device 16 to display instruction information corresponding to the instruction number determined in the instruction number determination processing.

After the LED display process, the main CPU 301 moves to the command transmission process (S209). As described above, various commands are stored in the command storage area of the main RAM 303 in the game control process. The command stored in the command storage area is transmitted to the sub control board 400 in the command transmission process.

After the command transmission processing, the main CPU 301 executes register restoration processing (S210) and restores the data saved in step S210 to the register. When the register return process is executed, the main CPU 301 returns the process to step S of the game control process that was being executed when the interrupt process was started.

FIG. 48 is a flowchart of the display information control process of the main CPU 301. The display information control process is a process for displaying the display information on the main display 40. The main CPU 301 executes the display information control process, for example, every time one game ends.

When the display information control process is started, the main CPU 301 determines whether or not medals have been paid out in this game (whether or not a winning combination has been won) (S801). When determining that the medals have not been paid out (S801: NO), the main CPU 301 moves to step S806 described later. On the other hand, when it is determined that the medals have been paid out in this game (S801: YES), the main CPU 301 shifts to the ring buffer addition process (S802).

In the ring buffer addition process, the main CPU 301 adds the ring buffers (X to Z) described above. Specifically, the main CPU 301 adds the unit storage area x1 of the ring buffer X in the ring buffer addition process. If the current game is in the bonus operation state, the unit storage area y1 of the ring buffer Y is added to the unit storage area x1. Furthermore, when the game this time is in the BB state, the unit storage area z1 of the ring buffer Z is added to the unit storage area x1 and the unit storage area y1.

After executing the ring buffer addition processing, the main CPU 301 determines whether or not one set has been completed in this game (whether or not 400 games have been executed since the last set was completed) (S803). ). When it is determined that one set is not finished in the game this time (S803: NO), the main CPU 301 shifts to step S806 described later. On the other hand, when it is determined that one set is finished in the game this time (S803: YES), the main CPU 301 updates the set cumulative storage area (a to c) (S804).

Specifically, the main CPU 301 stores the sum of the numerical values stored in each unit storage area x (1 to 15) of the ring buffer X in the set cumulative storage area a. Further, the main CPU 301 stores the sum of the numerical values stored in the unit storage areas y (1 to 15) of the ring buffer Y in the set cumulative storage area b. Further, the main CPU 301 stores the sum of the numerical values stored in each unit storage area z (1 to 15) of the ring buffer Z in the set cumulative storage area c.

After updating the set cumulative storage area, the main CPU 301 calculates the latest bonus ratio and the latest BB ratio (S805). Specifically, the main CPU 301 calculates the latest bonus ratio and the latest BB ratio using each set cumulative storage area (a to c) updated in step S804 described above. For example, the main CPU 301 calculates a quotient (ratio) when the cumulative storage area a is divided into the cumulative storage area b, and stores a numerical value obtained by multiplying the calculation result by 100 as the latest bonus proportion in the proportion storage area g1. Further, the main CPU 301 calculates a quotient (ratio) when the cumulative storage area a is divided into the cumulative storage area c, and stores a numerical value obtained by multiplying the calculation result by 100 as the latest BB proportion in the ratio storage area g2.

After calculating the latest bonus ratio and the latest BB ratio, the main CPU 301 determines whether or not the total number of games has reached 175,000 or more (S806). When determining that the total number of games has reached 175,000 or more (S806: YES), the main CPU 301 shifts to the display mode changing process (S807).

In the display mode changing process, the main CPU 301 changes the display mode of each display information H (A to E). Specifically, in the first to 5999th games, the identification information Ib (latest BB rate) and the identification information Ic (latest bonus rate) displayed in a blinking display mode are temporarily the total number of games in this game. When it reaches 6000 times, it is changed to a lighting display mode.
In addition, the identification information Ia (regulation period ratio), the identification information Id (BB ratio), and the identification information Ie (bonus ratio) that are displayed in a blinking manner in the first to 174999th games are provisionally set in this game. When the total number of games reaches 175,000, the lighting display mode is changed.

In the display mode changing process, the main CPU 301 changes the display mode of the ratio information R according to the size of the game information indicated by the ratio information R(a to e). Specifically, when the restriction period ratio indicated by the ratio information Ra becomes 70% or more, the main CPU 301 changes the ratio information Ra to a blinking display mode so that the restriction period ratio indicated by the ratio information Ra becomes less than 70%. When it becomes, the ratio information Ra is changed to a lighting display mode. When the latest BB ratio indicated by the ratio information Rb is 60% or more, the main CPU 301 changes the ratio information Rb to a blinking display mode, and when it is less than 60%, the ratio information Rb is changed to a lighting display mode. change. The main CPU 301 changes the ratio information Rc to a blinking display mode when the latest bonus ratio indicated by the ratio information Rc is 70% or more, and changes the ratio information Rc to a lighting display mode when it is less than 70%. .. The main CPU 301 changes the ratio information Rd to a blinking display mode when the BB ratio indicated by the ratio information Rd is 60% or more, and changes the ratio information Rd to a lighting display mode when the BB ratio is less than 60%. The main CPU 301 changes the ratio information Re to a blinking display mode when the bonus ratio indicated by the ratio information Re is 70% or more, and changes the ratio information Re to a lighting display mode when the bonus ratio is less than 70%.

The above steps S801 to S807 are executed in each game regardless of the total number of games. On the other hand, steps S806 to S814 (hereinafter referred to as "processing X") shown below are executed in each game for which the total number of games is less than 175,000, and not executed when the total number of games exceeds 175,000. That is, the process X is executed in each game of the total game counting period, and is not executed in each game after the total game counting period is finished.

When it is determined that the total number of games is less than 175,000 in step S806 described above (S806: NO), the main CPU 301 adds the numerical value “1” to the total game storage area that stores the total number of games (S808). .. After adding the total game storage area, the main CPU 301 determines whether or not the game this time is in the restriction period (S809). When it is determined that the current game is not in the restricted period (S809: NO), the main CPU 301 shifts to step S811. On the other hand, if it is determined that the current game is in the regulation period (S809: YES), the main CPU 301 adds the numerical value “1” to the regulation period storage area that stores the total number of games in the regulation period (S810). After that, the main CPU 301 calculates the regulation period ratio (S811). For example, in step S810 described above in the current game, when the restriction period storage area is added, the restriction period ratio increases from the previous game. On the other hand, in the current game, if the restriction period storage area is not added, the restriction period ratio is reduced from the previous game. The regulation period ratio calculated by the main CPU 301 is stored in the ratio storage area G3.

After calculating the regulation period ratio, the main CPU 301 determines whether or not one set is finished in the game this time (S812). When it is determined that one set has been completed in this game (S812: YES), the main CPU 301 adds the total cumulative storage area (A to B) (S813). Specifically, the main CPU 301 adds, to the total cumulative storage area A, the unit storage area x1 in which the total payout number for the current set is stored. Further, the main CPU 301 adds the unit storage area y1 in which the total number of payouts in the bonus operation state of the current set is stored to the total cumulative storage area B. Further, the main CPU 301 adds, to the total cumulative storage area C, the unit storage area z1 in which the total payout number in the BB state of the current set is stored.

In step S813 after adding the total cumulative storage area, the main CPU 301 stores (moves) each numerical value stored in the unit storage area xn (n is an integer of 1 to 14) in the unit storage area xn+1, and the unit storage area Initialize x1 to the value "0". Further, the main CPU 301 stores (moves) each numerical value stored in the unit storage area yn (n is an integer of 1 to 14) in the unit storage area yn+1, and initializes the unit storage area y1 to the numerical value “0”. Further, the main CPU 301 stores (moves) each numerical value stored in the unit storage area zn (n is an integer of 1 to 14) in the unit storage area zn+1, and initializes the unit storage area z1 to the numerical value “0”. The above process is executed in step S804 after the set cumulative storage area is updated in the period after the total game storage period ends and the process X (step S813) is not executed.

After that, the main CPU 301 calculates the bonus rate and the BB rate (S814). The bonus ratio calculated by the main CPU 301 is stored in the ratio storage area G1, and the BB ratio is stored in the ratio storage area G2. When the bonus rate and the BB rate are calculated, or when it is determined in step 812 that one set is not completed (S812: NO), the main CPU 301 executes step S807 described above and displays the display information. The control process ends.

<Each process executed by the sub CPU>
FIG. 49 is a flowchart of the sub activation process of the sub CPU 412. The sub CPU 412 executes sub activation processing when a reset signal from the reset circuit is input. The reset circuit outputs a reset signal when the power supply voltage supplied to the sub control board 400 exceeds a predetermined threshold value. For example, when the supply of the power supply voltage to the sub control board 400 is started, the sub starting process is executed.

When the sub-startup processing is started, the sub-CPU 412 executes start-up initialization processing (S301). In the startup initialization process, the sub CPU 412 initializes various registers of the sub control board 400, for example.

In the startup initialization process, the sub CPU 412 determines whether there is a backup abnormality of the sub RAM 414. If there is a backup abnormality, the sub CPU 412 initializes the backup data. In addition, the sub CPU 412 determines whether or not the data stored in various ROMs including the CGROM 424 is proper in the startup initialization process. For example, the data stored in a specific address of each ROM is read out and it is determined whether the data is proper or not. When an abnormality is found in each ROM, the sub CPU 412 shifts to a predetermined error process.

In the sub activation process, the sub CPU 412 activates the lamp control task (S302), activates the acoustic control task (S303), activates the image control board communication task (S304), activates the main control board communication task (S305), and effects. The button input task is activated (S306).

FIG. 50 is a flowchart of each task activated in the sub activation process. The sub CPU 412 controls various lamps including the housing lamp 5 and the effect lamp 28 by a lamp control task. Further, the sub CPU 412 controls the speakers (31, 32) by the sound control task. Further, the sub CPU 412 transmits a command to the image control board 420 by the image control board communication task, receives a command from the main control board 300 in the main control board communication task, and produces the effect button 26 and the direction in the effect button input task. The operation of the designation button 27 is accepted.

A timer interrupt signal is input to the sub CPU 412 at predetermined time intervals. Upon receiving the timer interrupt signal, the sub CPU 412 executes any of the tasks. That is, each peripheral device including various lamps and speakers (31, 32) is time-divisionally controlled.

FIG. 50A is a flowchart of the lamp control task. When the lamp control task is started, the sub CPU 412 initializes data for controlling various lamps (S302-1). After initializing various data, the sub CPU 412 proceeds to the lamp data analysis process (S302-2). The lamp data is data indicating blinking patterns of various lamps. For example, a time series of data indicating a time for turning on a specific lamp and data indicating a time for turning off the lamp (300 ms lighting→300 ms lighting→300 ms lighting→...) Can be adopted as the lamp data.

In the lamp control process (S302-3), the sub CPU 412 blinks a specific lamp in a manner designated by the lamp data. The lamp data analysis process and the lamp effect execution process are repeatedly executed until the timer interrupt signal is input.

FIG. 50B is a flowchart of the sound control task. When the acoustic control task is started, the sub CPU 412 initializes various data for controlling the speakers (31, 32) (S303-1). After initializing various data, the sub CPU 412 moves to acoustic data analysis processing (S303-2).

In the sound control process (S303-3), the sub CPU 412 gives an instruction to the sound board 430 (sound source IC 431) according to the result of the sound data analysis process. The sound source IC 431 reads acoustic data from the sound source ROM 432 according to an instruction from the sub CPU 412, generates an acoustic signal from the acoustic data, and supplies the acoustic signal to the speakers (31, 32 ). The acoustic data analysis process and the acoustic control process are repeatedly executed until the timer interrupt signal is input.

FIG. 50C is a flowchart of the image control board communication task. When starting the image control board communication task, the sub CPU 412 determines whether or not the non-gaming timer has timed out (S304-1). The non-gaming timer is timed up when the non-gaming state has continued for a predetermined time since the previous game was over. Specifically, the non-gaming timer is set to an initial value at the time when the previous game is finished, and is decremented every predetermined period during the non-gaming period. For example, the non-gaming timer is timed up when the non-gaming period has continued for 1 minute since the previous game was over. The non-gaming timer is provided in the sub RAM 414, for example.

When determining that the non-gaming timer has timed out (S304-1: YES), the sub CPU 412 moves to the demo display command transmission process (S304-2) and transmits the demo display command to the image control board 420. When receiving the demo display command, the image control board (image control CPU 421) 420 causes the liquid crystal display device 30 to display a demonstration image. Further, the sub CPU 412 turns off various lamps during the period in which the demonstration image is displayed.

On the other hand, when it is determined that the non-gaming timer has not timed out (S304-1: NO), the sub CPU 412 sets a command according to the effect number stored in the sub RAM 414 (S304-3). The effect number indicates the type of effect executed in the gaming machine 1, and is stored in the effect number storage area of the sub RAM 414 in the effect lottery process described later. The sub CPU 447 transmits the command set in step S304-3 to the image control board 420 (S304-4), and ends the image control board communication task. The image control board communication task may be configured to be able to receive a command from the image control board 420.

FIG. 50(d) is a flowchart of the main control board communication task. When the main control board communication task is started, the sub CPU 412 executes communication start preprocessing (S305-1) for initializing a predetermined storage area. After executing the pre-communication start processing, the sub CPU 412 proceeds to the reception command check processing (S305-2). In the received command check processing, the content of the command received from the main control board 300 is checked.

The sub CPU 412 determines whether or not the command checked in the current received command check processing is different from the command checked in the previous received command check processing (S305-3). That is, in step S305-3, the sub CPU 412 determines whether the command from the main control board 300 has changed. The sub CPU 412 repeatedly executes step S305-3 until the command from the main control board 300 changes (S305-3: NO). When the command from the main control board 300 has changed (S305-3: YES), the sub CPU 412 proceeds to command analysis processing (S305-4).

After executing the command analysis process, the sub CPU 412 executes the game information update process (S305-5). In the game information update process, the sub CPU 412 updates the game information stored in the sub RAM 414 according to the command received from the main control board 300. In step S305-5, the sub CPU 412 executes any one of a plurality of types of game information update processing. Specifically, the sub CPU 412 executes game information update processing according to the type of command received from the main control board 300 among the plurality of types of game information update processing. For example, when receiving the start operation command, the sub CPU 412 executes a game information update process for updating the remaining number of games in the AT state displayed on the liquid crystal display device 30. After updating the game information, the sub CPU 412 returns the processing to step S305-2, and repeats the processing from step S305-2 to step S305-5 until the next timer interrupt signal is input.

FIG. 51 is a flowchart of command analysis processing. When starting the command analysis process, the sub CPU 412 executes the effect control process (S401). As described later, in the effect control process, the sub CPU 412 determines, for example, an effect to be executed by the gaming machine 1.

After executing the effect control process, the sub CPU 412 determines lamp data according to the effect (S402), and stores the lamp data in the sub RAM 414 (S403). In addition, the sub CPU 412 determines acoustic data according to the effect determined in the effect control processing (S404), and stores the determined acoustic data in the sub RAM 414 (S405). After storing the acoustic data, the sub CPU 412 ends the command analysis process.

FIG. 52 is a flowchart of the effect control process. When the effect control process is started, the sub CPU 412 determines whether the command received from the main control board 300 is a setting change start command or a setting value command (S401-1). If the sub CPU 412 determines that the command received from the main control board 300 is the setting change start command or the setting value command (S401-1: YES), the sub CPU 412 proceeds to the setting change start/end process (S401-2).

Specifically, when determining that the setting change start command has been received, the sub CPU 412 notifies that the setting change process is being executed. For example, the sub CPU 412 causes the liquid crystal display device 30 to display a message “settings are being changed” and causes each speaker to output the voice of the message. When it is determined that the set value command has been received (that is, when the setting change process has ended), the sub CPU 412 stores the set value indicated by the set value command in the sub RAM 414 and ends the notification of the setting change process. To do. After executing the setting change start/end processing, the sub CPU 412 ends the effect control processing.

When it is determined that the command received from the main control board 300 is not the setting change start command or the setting value command (S401-1: NO), the sub CPU 412 determines whether or not the closing command is received (S401-3). ). When it is determined that the input command is received (S401-3: YES), the sub CPU 412 proceeds to the input command reception process (S401-4). In the insertion command reception process, the sub CPU 412 generates, for example, an effect at the time of inserting a medal. After executing the closing command reception process, the sub CPU 412 ends the effect control process.

When the sub CPU 412 determines that the received command is not the input command (S401-3: NO), the sub CPU 412 determines whether or not the settlement operation command is received (S401-5). When it is determined that the settlement operation command is received (S401-5: YES), the sub CPU 412 proceeds to the settlement operation command reception process (S401-6). In the processing upon receipt of the payment operation command, the sub CPU 412 notifies that the payment of the medal is being executed. In the process at the time of receiving the adjustment operation command, the sub CPU 412 causes the liquid crystal display device 30 to display, for example, a message "In process of adjustment" and outputs a predetermined warning sound from the speaker. After executing the payment operation command reception process, the sub CPU 412 ends the effect control process.

When determining that the received command is not the settlement operation command (S401-5: NO), the sub CPU 412 determines whether or not the start operation command has been received (S401-7). When determining that the start operation command has been received (S401-7: YES), the sub CPU 412 proceeds to the start operation time process (S401-8). In the start operation process, the sub CPU 412 executes various processes including the effect lottery process. After executing the process at the time of start operation, the sub CPU 412 ends the effect control process.

When determining that the received command is not the start operation command (S401-7: NO), the sub CPU 412 determines whether or not a reel start command has been received (S401-9). When it is determined that the reel start command is received (S401-9: YES), the sub CPU 412 proceeds to the reel start command reception process (S401-10). In the process at the time of receiving the reel start command, the sub CPU 412 causes the speaker to output, for example, a reel rotation sound that is output when the rotation of the reel is started. After executing the process at the time of receiving the reel start command, the sub CPU 412 ends the effect control process.

When determining that the received command is not the reel start command (S401-9: NO), the sub CPU 412 determines whether a stop operation command has been received (S401-11). When it is determined that the stop operation command is received (S401-11: YES), the sub CPU 412 proceeds to the stop operation time process (S401-12). In the stop operation process, for example, the display mode of the liquid crystal display device 30 is switched. After executing the stop operation time process, the sub CPU 412 ends the effect control process.

When the sub CPU 412 determines that the received command is not the stop operation acceptance command (S401-11: NO), whether or not the display winning combination command (re-game command, winning winning combination command or lost display command) is received. Is determined (S401-13). When it is determined that the display winning combination command is received (S401-13: YES), the sub CPU 412 proceeds to the display winning combination command reception process (S401-14).

When determining that the received command is not the display winning combination command (S401-13: NO), the sub CPU 412 determines whether a payout start command or a payout end command has been received (S401-15). When it is determined that the payout start command or the payout end command is received (S401-15: YES), the sub CPU 412 executes a payout sound control process (S401-16). For example, when the sub CPU 412 receives the payout start command, the sub CPU 412 starts outputting a medal payout sound for notifying the ejection of medals. When the payout end command is received, the sub CPU 412 stops the medal payout sound. After executing the payout sound control process, the sub CPU 412 ends the effect control process.

<Second Embodiment>
The second embodiment of the present invention will be described below. It should be noted that in each of the following exemplary embodiments, the elements having the same functions and functions as those in the first embodiment are assigned the reference numerals used in the description of the first embodiment, and the detailed description thereof is appropriately omitted.

FIG. 53A is a diagram for explaining the transition of the game state in the second embodiment. The gaming machine 1 of the second embodiment is a so-called "A type" gaming machine that can obtain many medals mainly in the bonus operation state. In the gaming machine of the second embodiment, similarly to the gaming machine of the first embodiment, when the bonus combination (BB combination, RB combination) is won in the normal state, the state shifts to the internal middle state, and then the bonus combination symbol When the combination is stopped and displayed on the activated line, the bonus operation state (BB state, RB state) is entered. In addition, when the bonus operation state ends, the state shifts to the normal state.

The second embodiment is different from the first embodiment in that the AT state and the chance state are not provided. In the above-described second embodiment, the precursory state for shifting to the AT state or the chance state and the start preparation state for shifting to the AT state are not provided. That is, in the second embodiment, the instruction period is not provided, and the instruction display unit 16 does not instruct the stop operation sequence. Further, in the second embodiment, no regulation period is provided.

FIG. 53B is a simulated diagram of the main display 40 that displays the display information HA in the second embodiment. Similar to the display information HA of the first embodiment, the display information HA of the second embodiment displays the identification information Ia corresponding to the regulation period ratio. However, while the display information HA of the first embodiment displays the ratio information Ra indicating the size of the regulation period ratio (see FIG. 23A), the display information HA of the second embodiment displays the ratio. The non-installed information N is displayed instead of the information Ra.

As described above, the ratio information Ra displays the numbers “00” to “99”, while the non-installed information N displays symbols other than the numbers, as shown in FIG. 53B. Specifically, the non-installed information N displays two symbols "-" (hyphen). In the gaming machine 1 of the second embodiment, the display information HB to the display information HE display the identification information I(b to e) and the ratio information R(b to e) as in the first embodiment.

By the way, in a gaming machine having no regulation period, the number of games played during the regulation period is always zero. Therefore, it is conceivable to adopt a configuration (hereinafter referred to as "comparative ratio") for displaying the identification information Ia and the ratio information Ra representing the number "00" in the gaming machine in which the regulation period is not provided. However, even with a gaming machine provided with a regulation period, when the number of games during the regulation period is 0, the ratio information Ra of the display information HA displays the number "00". That is, the display information HA “7U.00” common to the gaming machines provided with the regulation period and the gaming machines not provided with the regulation period is displayed.

In the above-mentioned proportionality, it is not possible to identify from the display information HA whether or not the gaming machine can shift to the regulation period. Therefore, in the second embodiment, the non-installed information N different from the ratio information Ra is displayed in the display information HA in the gaming machine in which the regulation period is not provided. In the above configuration, by displaying the non-installed information N on the main display 40 (second display unit 40Y) of the gaming machine, it is possible to identify that the gaming machine is not a gaming machine that can enter the regulation period. ..

In the above second embodiment, in the gaming machine in which the regulation period is not provided, the display information HA displays the non-mounted information N, but the non-mounted information N is displayed in the other display information H (B to E). May be displayed as a game machine.

For example, as another example of the second embodiment, assume a gaming machine that cannot enter the BB state (a BB combination is not provided). In the above gaming machine, the latest BB ratio and the BB ratio cannot be updated even if the game progresses. In the above gaming machine, the display information HB displays the identification information Ib (corresponding to the latest BB ratio) and the non-installed information N. Further, the display information HD displays the identification information Id (corresponding to the BB ratio) and the non-installed information N. According to the above configuration, the gaming machine can recognize that the BB state is not provided and the latest BB ratio and the BB ratio cannot be updated. Note that the above gaming machine has a regulation period and shifts to the RB state. In the above case, the display information HA, the display information HC, and the display information HE display the identification information I(a, c, e) and the ratio information R(a, c, e), as in the first embodiment.

Further, as a specific example of the above-mentioned gaming machine, it is assumed that the gaming machine cannot shift to the RB state in addition to the BB state (the BB role and the RB role are not provided). In the above gaming machine, in addition to the latest BB ratio and the BB ratio, the latest bonus ratio and the bonus ratio cannot be updated even when the game progresses. In the above gaming machine, the display information HB displays the identification information Ib and the non-installed information N, the display information HD displays the identification information Id and the non-installed information N, and the display information HC is the identification information Ic (the latest bonus). The display information HE displays the identification information Ie (corresponding to the bonus rate) and the non-installed information N. According to the above configuration, it is possible to recognize that the gaming machine is not provided with the bonus operation state (RB state and BB state), and the latest BB ratio, the BB ratio, the latest bonus ratio, and the bonus ratio cannot be updated. is there. The above gaming machine has a regulation period. In the above case, the display information HA displays the identification information Ia and the ratio information Ra, as in the first embodiment.

As described above, in the second embodiment, various game information (regulation period ratio, BB ratio, bonus ratio, latest BB ratio, latest bonus ratio) is updated according to the progress of the game, and corresponding to each game information. In the case where the first display unit 40X capable of displaying various identification information I(a to e) and the first display unit 40X display the identification information I, the game information corresponding to the identification information is the game. When it can be updated according to the progress, the size of the game information (ratio information R) can be displayed, and the first display section 40X displays the identification information I, which corresponds to the identification information. When the game information cannot be updated in accordance with the progress of the game, the second display unit 40Y capable of displaying the predetermined non-installed information N is provided.

According to the above configuration, when the first display means displays the identification information and the game information corresponding to the identification information can be updated according to the progress of the game, the size of the game information is displayed. When the first display means displays the identification information and the game information corresponding to the identification information cannot be updated according to the progress of the game, the predetermined non-installed information is displayed. It is possible. Therefore, it is possible to easily recognize whether or not the game information corresponding to the displayed identification information can be updated according to the progress of the game, depending on whether or not the non-installed information is displayed.

<Third Embodiment>
FIG. 54A is a diagram for explaining the storage area of the main RWM (Read write memory) in the third embodiment. The main RWM has both the functions of the main ROM 302 and the main RAM 303 in the above-described first embodiment.

As shown in FIG. 54A, the storage area of the main RWM includes a first data area, a second data area, and an empty data area. As shown in FIG. 54(a), the first data area is provided at addresses in a continuous range of the main RWM. Similarly, the second data area is provided at addresses in a continuous range of the main RWM. The empty data area is provided between the first data area and the second data area. The empty data area is provided at addresses in a continuous range of the main RWM and has a size of 16 bytes or more.

As shown in FIG. 54A, the first data area stores various data including a game control program and game control data. The game control program causes the main CPU 301 to execute various processes including a process for advancing the game (game control process and the like). Further, the game control data is used in various processes executed by the game control program. The various data in the first data area described above includes data that affects the game play (for example, a winning area lottery table). Further, the first data area includes an area (a stack area or the like) in which various data used in the processing executed by the game control program are temporarily stored.

As shown in FIG. 54A, the second data area stores various data including the display information program and the display information data. The display information program causes the main CPU 301 to execute the process of displaying the above-described display information H on the main display 40. Specifically, the display information program causes the main CPU 301 to execute various processes including the above-described display information control process. In addition, the display information data is various data for displaying each display information H on the main display 40. For example, the display information data includes light emission pattern data for each display information H. The light emission pattern data can specify the segment of the main display 40 (7-segment display) that emits light when the display information H is displayed. When displaying the display information H, the main CPU 301 causes the segment specified by the light emission pattern data of the display information H to emit light. The various data in the second data area described above does not include data that affects game playability. Further, the second data area includes an area (a stack area or the like) in which various data used in the processing executed by the display information program are temporarily stored.

The empty data area is an area in which various data are not stored. Specifically, only the numerical value "0" is stored in the empty data area. As shown in FIG. 54A, the area between the first data area and the second data area is all empty data area. In the specific example of FIG. 54A, from the memory area of the main RWM, from Addr (address) “XX(Y−1)0” (X and Y are hexadecimal numbers “0 to F”). An empty data area is provided in the range of Addr “XX(Y−1)F”.

By the way, when inspecting a game machine, a dump list (hexadecimal dump) may be generated from each data stored in the main RWM, and each data stored in the main RWM may be checked using the dump list. When confirming each data stored in the main RWM, it is possible to separately confirm each data in the first data region (relatively important) that affects the game playability and each data in the second data region that does not affect the game playability. Certain configurations are preferred. Therefore, in the third embodiment, in the dump list, each data in the first data area and each data in the second data area can be easily distinguished and confirmed.

FIG. 54(b) is a specific example of the dump list generated from each data of the main RWM in the third embodiment. One byte of data is stored in one address of the main RWM. In FIG. 54B, each data stored in each address is represented by a hexadecimal number “xx”. Each "x" in FIG. 54(b) means any of "0 to F". Further, each "x" in FIG. 54(b) may have a different numerical value.

As described above, the first data area is provided in a continuous range of addresses. In the specific example of FIG. 54B, each data of the first data area is stored in the range from Addr “XX00” to Addr “XX(Y−2)F”. Further, the second data area is provided in a continuous range of addresses, like the first data area.

The head of the second data area in the third embodiment is located at an address that is a multiple of 16 in the storage area of the main RWM. In the specific example of FIG. 54B, the start address of the second data area is Addr “XXY0” (decimal number “163×X+162×X+16×Y+0”). As can be seen from FIG. 54(b), each data item at an address that is a multiple of 16 in the storage area of the main RWM is located in the leftmost column (column “+0”) of the dump list. That is, according to the configuration of the third embodiment, it can be said that the head of the second data area is located in the leftmost column of the dump list.

As described above, the empty data area and the second data area are continuous storage areas, and the beginning of the second data area is located at an address that is a multiple of 16. In the above configuration, as shown in FIG. 54(b), the end of the empty data area is located at an address that is a multiple of 15 (hexadecimal "F"). That is, it is also said that the end of the empty data area is located in the rightmost column (column of “+F”) of the dump list.

The empty data area of the third embodiment has a size of 16 bytes or more. In the above configuration, 16-byte or more numeric value "00" data is interposed between the first data area and the second data area. As described above, the end of the empty data area is located in the rightmost column of the dump list, and 16 bytes of data are displayed in one horizontal line from the right edge to the left edge of the dump list. With the above configuration, among the data of the dump list, each data in at least one column immediately before the second data area displays the numerical value “00” of the empty data area.

In the specific example of FIG. 54B, it is assumed that the empty data area is 16 bytes. In the above case, all the data in one line starting from Addr "XX(Y-1)0" (Addr "XX(Y-1)0" to Addr "XX(Y-1)F") is "00". Is displayed. Further, in the above specific example, as shown in FIG. 54B, the first data area is in the range of Addr “XX00” to Addr “XX(Y−2)F”.

According to the third embodiment described above, in the dump list generated from each data stored in the main RWM, an area in which each data in the first data area is displayed and an area in which each data in the second data area is displayed. There is one line of "00" for all the data. In the above dump list, each data in the first data area and each data in the second data area can be easily distinguished. For example, when confirming each data in the first data area, it is only necessary to confirm each data displayed above the row of "00" for all data. Further, when confirming each data in the second data area, it is sufficient to confirm each data displayed below the line where all the data are “00”.

<Modification>
Each of the above forms can be modified in various ways. Specific modes of modification will be exemplified below. Two or more aspects arbitrarily selected from the following examples can be appropriately merged.

(1) The trigger for switching each display information H may be changed appropriately. For example, the main display unit 40 may switch and display the display information H each time a predetermined operation unit (for example, a setting change button) is operated. Further, in the configuration in which the display information H is switched at a predetermined time interval, the time interval at which the display information H is switched can be changed appropriately. For example, it is preferable that the display information H be switched at a predetermined time interval of about 4.5 seconds to about 5.5 seconds.

(2) In each of the above-described modes, each display information may be displayed on a display different from the main display 40. For example, the ratio information R(a to e) may be displayed on the instruction display device 16 and the identification information I(a to e) may be displayed on the stored sheet number display device 17. Further, each display information H may be displayed by either the instruction display device 16 or the stored number display device 17. The instruction indicator 16 is a 2-digit 7-segment display. However, in order to display the display information H at once, a 4-digit 7-segment display is required. Therefore, as a configuration for displaying each display information H on the above-mentioned instruction display device 16, an operation of displaying the identification information I and then displaying the ratio information Ra indicating the size of the game information of the identification information I is performed. A configuration is conceivable in which the instruction display 16 is repeated for each piece of identification information I.

In the configuration in which the display information H is displayed on the display device (the instruction display device 16 or the like) that can be visually recognized by the player as in the above modification example, a configuration that requires a special operation to display the display information H is preferable. Is. For example, in the configuration in which the setting change button provided inside the gaming machine 1 can be operated by the administrator of the gaming machine 1, a configuration in which the display information H can be displayed when the setting change button is operated can be considered.

(3) In each of the above-described embodiments, each 7-segment display of the main display 40 is arranged in a line in the left-right direction. However, the arrangement of each 7-segment display of the main display 40 can be changed as appropriate. For example, each 7-segment display may be arranged in a line in the vertical direction. The 7-segment displays may be arranged in a matrix of 2 rows and 2 columns, or may be arranged in an L-shape or a U-shape.

(4) In each of the above modes, each ring buffer (X to Y) can be changed appropriately. For example, in each of the above embodiments, the ring buffer is composed of 15 unit storage areas, but the ring buffer may be composed of 2 to 14 unit storage areas. According to the above configuration, it is possible to reduce the storage capacity of the ring buffer as compared with the case where the ring buffer is composed of 15 unit storage areas.

Further, in each of the above-described modes, the size of each storage area can be changed appropriately. For example, in the above-described first embodiment, the total cumulative storage area (A to C), the restriction period storage area D, and the total game storage area E are configured to be 4 bytes, but for example, each storage area described above is configured to be 3 bytes. You may comprise.

(5) In each of the above-described modes, the ring buffer, the set cumulative storage area, the total cumulative storage area, the regulation period storage area, and the total game storage area have a configuration that cannot be initialized by each processing including the initialization processing at the time of power-off. It is suitable. However, if the data in each storage area described above is destroyed, or if a cold start is performed, the data in each storage area is initialized.

(6) In the third embodiment described above, various types of data used in the processing executed by the game control program may be temporarily stored in the empty data area. Further, various types of data used in the processing executed by the display information program may be temporarily stored in the empty data area. However, when each data stored in the empty data area is used in both the process executed by the game control program and the process executed by the display information program (for example, in the game control program and the display information program If the common storage area can be rewritten in each process), the possibility that the process in the display information program affects the result of the game is not completely excluded. In consideration of the above circumstances, it is preferable that each data stored in the empty data area is used only in one of the process executed by the game control program and the process executed by the display information program. ..

(7) In each of the above-described embodiments, “the total value of the game information in one unit period in each unit period repeated each time a predetermined game condition is satisfied is stored in a plurality of unit storages each time the game condition is satisfied. When the present set is completed, for example, the payout number in the present set is set as a unit, and the storage means for sequentially storing in the area and the updating means for updating the game information that can be stored in the unit storage area are provided. A configuration is adopted in which the values are stored in the storage area x1, the numerical values in the unit storage area x15 are discarded, and the numerical values in the unit storage area x2 to the unit storage area x14 are moved (see FIG. 21). However, instead of the above configuration, when the current set ends, the unit storage area for storing the oldest game information of each unit storage area of the ring buffer may be overwritten with the game information in the current set. Good. According to the above configuration, the game information of the latest 15 sets is stored in the unit storage area for each set, as in each of the above-described modes.

(8) In each of the above-described modes, the cycle in which the identification information I or the ratio information R blinks in the blinking display mode can be appropriately changed. In the blinking display mode, for example, a configuration in which the identification information I or the ratio information R blinks at a time interval of about 0.54 seconds to about 0.66 seconds is preferable.

(9) If the four sides of the main display unit 40 are close to other electronic components (hereinafter referred to as “comparative”), an unauthorized electronic component is mounted between the main display unit 40 and the main control board 300. There is a circumstance that it may be difficult to confirm whether or not it is present. In particular, when the surface area of each electronic component mounted on the main control board 300 is equal to or larger than a certain size (6 mm 2) as in the above-described first embodiment, the above-described inconvenience is likely to be manifested. FIG. 55A is a cross-sectional view of the main control board 300 for explaining the above-mentioned contrast. In contrast with FIG. 55A, the electronic component x is provided close to the main display 40.

The arrow shown by the broken line in FIG. 55(a) indicates the range visible to the administrator when trying to confirm whether or not an unauthorized electronic component is mounted on the lower side of the main display 40. .. As can be seen from FIG. 55(a), in contrast, the electronic component x provided in the vicinity of the main display 40 cannot visually recognize between the main display 40 and the main control board 300. Therefore, the above-mentioned incontrast may cause the above-mentioned inconvenience. In consideration of the above circumstances, it is preferable that at least some of the four sides of the main display 40 are not in close proximity to other electronic components.

FIG. 55B is a cross-sectional view of the main control board 300 in the modification. The arrow indicated by the broken line in FIG. 55(b) indicates a range that can be visually recognized by the administrator, as in FIG. 55(a). As shown in FIG. 55B, a test area is provided on the surface of the main control board 300 in the modification. A test part for testing the operation of the gaming machine 1 can be mounted in the test area. For example, when testing the operation of the gaming machine 1 before being installed in the game arcade, test components are mounted in the test area of the main control board 300. Various signals are input from the test parts to the main control board 300 to test the operation of the gaming machine 1. Since the above test parts are removed when the player plays the game, no electronic parts are mounted in the test area.

In the modified example of FIG. 55(b), the main display 40 is mounted near the test area. Further, no other electronic component is mounted between the test area and the main display 40. According to the above modification, at least a part of the four sides of the main display unit 40 is not in close proximity to other electronic components, so that the lower side of the main display unit 40 can be easily viewed. Therefore, it is possible to suppress the above-described inconvenience that makes it difficult to confirm whether or not an unauthorized electronic component is mounted between the main display 40 and the main control board 300.

(10) In each of the above-described embodiments, no electronic component is mounted on the surface of the main control board 300 from the upper edge E to the area where the main display 40 is provided (see FIG. 6). Further, the manufacturer name and model identifier are displayed on the surface of the main control board 300. In the above configuration, the manufacturer name and model identifier may be displayed between the upper edge E and the main display 40. With the above configuration, as in the first embodiment described above, when viewed from the upper edge E side of the main control board 300, the main display unit 40 does not overlap with other electronic components, and thus the main display unit 40 and the main display unit 40 are not overlapped. It is possible to easily confirm whether or not an unauthorized electronic component is mounted between the control board 300 and the control board 300.

(11) Although the BB state of each of the above-described forms ends when 297 or more medals are paid out, the number of medals at which the BB state ends is not limited to the above example. For example, the BB state may be terminated when 465 or more medals are paid out.

Further, when a specific symbol combination is stopped and displayed, the winning state may be changed to a challenge state (so-called “CB”) in which the winning combination can be stopped and displayed regardless of the result of the internal lottery process. The above challenge state ends with one game, and when the medals are paid out in the challenge state, the unit storage area x1 and the unit storage area y1 are added as in the case where the medals are paid out in the RB state described above. To be done. Furthermore, when a specific symbol combination is stopped and displayed, it may be configured to shift to the SB state in which the winning probability of the winning combination increases. The above SB state ends with one game, and when the medals are paid out in the SB state, the unit storage area x1 and the unit storage area y1 are added in the same manner as when the medals are paid out in the RB state described above. To be done. That is, when the medals are paid out in the challenge state or the RB state, the bonus rate and the latest bonus rate increase.

An MB state may be provided that allows continuous transition to the challenge state. The MB state ends when, for example, 253 or more medals are paid out. When the medals are paid out in the MB state, the unit storage area x1, the unit storage area y1, and the unit storage area z1 are added, as in the case where the medals are paid out in the BB state described above. That is, when the medals are paid out in the MB state, the BB ratio and the latest BB ratio increase. In each game in the MB state, 13 or 14 medals may be paid out according to the stop operation order, and the MB state may be finished by paying out 14 or more medals. With the above configuration, when 14 medals are paid out in the first game in the MB state, the MB state is ended in one game, and when 13 medals are paid out, the MB state is twice. Ends with the game. Therefore, in the first game in the MB state, by instructing the stop operation order in which 13 medals are paid out (for example, in the AT state), a maximum of 27 medals can be acquired in the MB state.

(12) The present invention can be applied to not only the above-described pachi-slot machine but also pachinko machines, other game machines, and game machines in general.

For example, it is possible to play a game ball in a game area, and the game ball is won in each prize hole including a general prize hole (electrical accessory such as electric chu) and a special prize hole provided in the game area. In this case, assume a pachinko machine in which a predetermined number of game balls are paid out. The above pachinko machine is equipped with a variable display device capable of variable display of symbols, and when a specific symbol combination is stopped and displayed on the variable display device, a game ball can be won at a special winning opening (hereinafter referred to as "special game state". )). In the general winning opening, gaming balls can be won in each gaming state including the normal gaming state and the special gaming state.

In the above configuration, the period from the start of the game to the hitting of a predetermined number (for example, 6000) of game balls is set as one set, and the game balls paid out in each set are set as unit storage areas x. It is stored in (1 to 15). In addition, the game balls paid out in the special game state in each set when the special winning opening is won are stored in each unit storage area y (1 to 15). Furthermore, the game balls paid out at the time of winning the general winning opening or the special winning opening in each set are stored in each unit storage area z (1 to 15). Further, each time one set is completed, the total cumulative storage area and the set cumulative storage area are updated with the numerical values of the respective unit storage areas, as in the first embodiment. However, when the total number of sets reaches M times (M is an integer of 16 or more), the update of the total cumulative storage area is stopped. Hereinafter, the period from the start of the game to the end of the set M times is referred to as “total period”.

According to the above configuration, the ratio of the number of game balls acquired in the latest 15 sets in the special game state to the special winning opening as a trigger to the total number of the game balls acquired in the last 15 sets is calculated. However, it can be displayed on the main display 40. Similarly, the ratio of the number of game balls obtained by winning the game balls to the general prize hole and the special prize hole to the total number of game balls acquired in the last 15 sets is calculated and displayed on the main display 40. It is possible. Further, in the special game state of the total period, the ratio of the number of game balls obtained by winning the game balls to the special winning opening to the total number of game balls obtained during the total period is calculated, and the main display 40 is displayed. It can be displayed. Similarly, the main display unit 40 calculates the ratio of the number of game balls obtained by winning the game balls to the general prize hole and the special prize hole in the total period to the total number of game balls acquired in the total period. Can be displayed.

The gaming machine of the present invention is, for example, the following gaming machine.

The gaming machine of the present invention controls the progress of the game and updates the game information (regulation period ratio, bonus ratio, BB ratio, latest bonus ratio, latest BB ratio) according to the progress of the game. a CPU 301), various electronic components including the game control means is mounted on the first surface, and a specific substrate that the first surface is not the electronic component is mounted on the second surface of the opposite side (the main control board 300), lid And a transparent substrate case in which an information display sticker for displaying specific information is affixed to the lid portion, and a specific substrate can be stored so that the lid portion and the first surface face each other. The display unit includes a specific display unit (main display 40) mounted on a region of the first surface of the specific substrate that does not face the information display sticker, and the display unit is substantially the same as the first surface of the specific substrate . provided in parallel, the specific display unit is provided in the vicinity of a specific portion of the outer edge of the first surface, the first surface located between the specific part and specified display means, also mounted any electronic components Instead, the game control means automatically starts to display the combination of the identification information corresponding to the game information and the numerical information indicating the size of the game information in the predetermined game period on the display unit after the power is turned on. After that, it can be displayed in the period in which the game progresses.

According to the above configuration, the numerical information indicating the size equal to or larger than the threshold value is displayed in the first display mode, and the numerical information indicating the size smaller than the threshold value is the second display mode different from the first display mode. Is displayed. In the above configuration, for example, when the upper limit value of the appropriate size of the game information is adopted as the threshold value of the present invention, if the size of the game information is appropriate, the numerical information is displayed in the first display mode, and the appropriate value is displayed. If the numerical value is equal to or larger than the numerical value, the numerical value information is displayed in the second display mode. Therefore, since it is possible to determine whether the size of the game information is proper or not by the display mode of the numerical information, it becomes easy to recognize whether or not the size of the game information is proper.

By the way, in the configuration in which the game information is displayed on the substantially plate-shaped display unit, there is a problem that an unauthorized electronic component is easily mounted on the lower side of the display unit. In particular, in a configuration in which a seal or the like is attached to the substrate case of the specific substrate, the visibility is blocked by the seal, and it is difficult to visually recognize the lower side of the display unit, so that the above-mentioned problems are likely to become apparent. In consideration of the above circumstances, the present invention provides the specific display means in the vicinity of a specific portion of the outer edge of the surface, and the surface of the surface located between the specific display means and the specific portion has any electronic component. It has a configuration in which no parts are mounted. According to the above configuration, when the specific display means is viewed from the specific portion (outer edge side), the area between the surface of the specific substrate and the specific display means can be directly visually recognized. Therefore, for example, as compared with the configuration in which the specific display means is surrounded by the electronic components, the above-described problem can be suppressed.

1... Gaming machine, 300... Main control board, 301... Main CPU, 302... Main ROM, 303... Main RAM, 304... Random number generator, 305... I/F circuit, 400... Sub control board, 410... Performance control board 411... I/F circuit, 412... Sub CPU, 413... Sub ROM, 414... Sub RAM, 420... Image control board, 421... Image control CPU, 422... Image control ROM, 423... VDP, 424... CGROM, 425 ... RAM, 430... Sound board, 431... Sound source IC, 432... Sound source ROM

Claims (1)

A game control means for controlling the progress of the game and updating the game information according to the progress of the game,
Various electronic components including the game control means is mounted on the first surface, and a specific substrate on which an electronic component to a second surface opposite from being mounted to the first surface,
A transparent substrate case that includes a lid portion, is capable of accommodating the specific substrate such that the lid portion and the first surface face each other, and an information display sticker for displaying specific information is attached to the lid portion. When,
A display unit having a substantially plate shape, and a specific display unit mounted on a region of the first surface of the specific substrate that does not face the information display seal,
The display unit is provided substantially parallel to the first surface of the specific substrate,
The specific display means is provided near a specific portion of the outer edge of the first surface ,
No electronic component is mounted on the first surface located between the specific display means and the specific portion,
The game control means automatically starts displaying a combination of identification information corresponding to the game information and numerical information indicating the size of the game information in a predetermined game period on the display unit after power is turned on. After that, a gaming machine that can be displayed during the progress of the game.

Images