JP7397485B2 - gaming machine - Google Patents

Description

The present invention relates to gaming machines such as pachi-slot machines and pachinko machines.

Conventional gaming machines have been proposed in which input/output ports, basic random number generators, and the like are connected to a CPU (Central Processing Unit) of a main controller via an internal bus (see, for example, Patent Document 1).

JP2009-268481A

However, for example, in the gaming machine disclosed in Patent Document 1, the main controller is provided with an input/output port, so the main controller is equipped with input devices such as a start lever, and output devices such as reels. It is necessary to connect via a wiring cable (for example, a so-called flat cable that can be connected with a harness). Therefore, in the configuration of the conventional gaming machine, there was a problem that the number of wiring cables connected to the board increased, and the size of the board of the main control device became large. Further, in the configuration of the conventional gaming machine, there was also a problem that the wiring cable between the board of the main control device and the peripheral devices became long .

The present invention has been made in view of these points, and provides a game in which the board size of the main control section can be reduced, and the length of the wiring cable connecting the main control section and peripheral devices can also be shortened. The purpose is to provide a machine.

In order to achieve the above object, according to the gaming machine according to the present embodiment, a gaming machine having the following configuration can be provided.

A main control unit (for example, main control unit 600 described below) that controls the progress of the game,
a sub-control unit (for example, sub-control unit 620 described below) that controls the production device in accordance with instructions from the main control unit;
a plurality of peripheral devices connected to the main control unit and capable of inputting and/or outputting signals to and from the main control unit,
The main control unit includes at least a main control board and a plurality of relay boards (for example, a drum device board 602 and a door relay board 603, which will be described later),
Each of the main control board and the plurality of relay boards includes a signal input/output unit (for example, a PIO circuit 705 described below) that inputs and outputs the signal, and a communication unit that can communicate with the outside using a predetermined communication method (for example, , a serial bus communication circuit 701 (described later), a control unit (for example, a controller 706 described later) that controls the operation of the signal input/output unit and the communication unit , and information capable of displaying information including the number of stored game values. comprising an input/output communication means (for example, an HB-LSI 700 to be described later) having a display drive unit (for example, an LED drive circuit 703 to be described later) capable of displaying the information on a display device ;
Each of the plurality of peripheral devices is connectable to the signal input/output section of the input/output communication means,
Communication is performed between the main control board and the relay board by connecting the communication section of the input/output communication means of the main control board and the communication section of the input/output communication means of the relay board. It is possible to
The main control board includes an arithmetic processing unit (for example, a main CPU, which will be described later) that performs arithmetic processing for controlling gaming operations, and a main control board that stores information necessary for the arithmetic processing by the arithmetic processing unit to execute the arithmetic processing. A game control means (for example, a main RAM described below) having a second storage section (for example, a main RAM described below) in which information necessary for the execution of the arithmetic processing by the arithmetic processing section is stored. For example, a gaming machine characterized in that a microprocessor 610 (to be described later) is implemented separately from the input/output communication means.

According to the gaming machine of the present invention having the above configuration, the board size of the main control section can be reduced, and the length of the wiring cable connecting the main control section and the peripheral devices can also be shortened .

It is a diagram showing the external structure of the gaming machine according to the present embodiment. It is a diagram showing the internal structure of the gaming machine according to the present embodiment. FIG. 2 is a block diagram showing the electrical configuration of the gaming machine according to the present embodiment. FIG. 2 is a diagram for explaining the functional flow of the gaming machine according to the present embodiment. FIG. 2 is a diagram for explaining the gameplay of the first gaming machine according to the present embodiment. It is a diagram for explaining the mode of the first gaming machine according to the present embodiment. It is a diagram showing various tables of the first gaming machine according to the present embodiment. It is a diagram showing various tables of the first gaming machine according to the present embodiment. It is a diagram showing a symbol arrangement table of the first gaming machine according to the present embodiment. It is a diagram showing an internal lottery table of the first gaming machine according to the present embodiment. It is a diagram showing a symbol combination table of the first gaming machine according to the present embodiment. It is a diagram showing a symbol combination table of the first gaming machine according to the present embodiment. It is a diagram showing a symbol combination table of the first gaming machine according to the present embodiment. It is a diagram showing a symbol combination table of the first gaming machine according to the present embodiment. It is a diagram for explaining the correspondence between the internal winning combination, the stop operation mode, the display combination, etc. of the first gaming machine according to the present embodiment. It is a diagram for explaining limit processing of the first gaming machine according to the present embodiment. It is a diagram showing the configuration of a winning flag storage area, a winning operation flag storage area, and a symbol code storage area of the first gaming machine according to the present embodiment. It is a diagram showing the configuration of a carryover combination storage area of the first gaming machine according to the present embodiment. It is a diagram showing the configuration of a gaming state flag storage area of the first gaming machine according to the present embodiment. It is a diagram showing the configuration of a mode flag storage area of the first gaming machine according to the present embodiment. It is a diagram showing the configuration of an operation stop button storage area of the first gaming machine according to the present embodiment. It is a diagram showing the configuration of a press order storage area of the first gaming machine according to the present embodiment. It is a flowchart showing main processing executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing a power-on process executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing medal reception/start check processing executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing an internal lottery process executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing a game start state control process executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing a process at the start of a game during an advantageous period, which is executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing reel stop control processing executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing a game end state control process executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing processing at the end of a game during an advantageous section, which is executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing periodic interrupt processing executed by the main control circuit of the first gaming machine according to the present embodiment. It is a flowchart showing an overview of sub-side control processing executed by the sub-control circuit of the gaming machine according to the present embodiment. It is a diagram showing an example of the configuration of a medalless gaming machine according to the present embodiment. It is a diagram showing an example of the configuration of a main control board of the gaming machine according to the present embodiment. It is a diagram showing the external structure of the second gaming machine according to the present embodiment. It is a block diagram showing the electrical configuration of the second gaming machine according to the present embodiment. It is a diagram for explaining the transition of the RT state of the second gaming machine according to the present embodiment. It is a diagram showing a symbol arrangement table of the second gaming machine according to the present embodiment. It is a diagram showing an internal lottery table of the second gaming machine according to the present embodiment. It is a diagram showing an internal lottery table of the second gaming machine according to the present embodiment. It is a diagram showing a symbol combination table of the second gaming machine according to the present embodiment. It is a diagram showing a symbol combination table of the second gaming machine according to the present embodiment. FIG. 7 is a diagram for explaining the correspondence relationship (general (normal) (non-internal)) between the internal winning combination, the stop operation mode, the display combination, etc. of the second gaming machine according to the present embodiment. FIG. 7 is a diagram for explaining the correspondence relationship (general (normal) (non-internal)) between the internal winning combination, the stop operation mode, the display combination, etc. of the second gaming machine according to the present embodiment. It is a diagram for explaining the correspondence relationship between the internal winning combination, the stop operation mode, the display combination, etc. (inside the RB) of the second gaming machine according to the present embodiment. It is a diagram for explaining the correspondence relationship between the internal winning combination, the stop operation mode, the display combination, etc. (inside the RB) of the second gaming machine according to the present embodiment. It is a diagram for explaining the correspondence relationship between the internal winning combination, the stop operation mode, the display combination, etc. (inside the BB) of the second gaming machine according to the present embodiment. It is a diagram for explaining the correspondence relationship between the internal winning combination, the stop operation mode, the display combination, etc. (inside the BB) of the second gaming machine according to the present embodiment. It is a diagram for explaining the gameplay of the second gaming machine according to the present embodiment. It is a table list of high probability zones and BIG probability zones of the second gaming machine according to the present embodiment. It is a table of a high probability zone and a BIG probability zone of the second gaming machine according to the present embodiment, and a correspondence table of zones. It is a list of tables in the consecutive game zone of the second gaming machine according to the present embodiment. It is a diagram showing a table type lottery table (RT0) of the second gaming machine according to the present embodiment. It is a diagram showing a table type lottery table (other than RT0) of the second gaming machine according to the present embodiment. It is a diagram showing the table type lottery table (RB in operation) of the second gaming machine according to the present embodiment. It is a diagram showing the table type lottery table (BB in operation) of the second gaming machine according to the present embodiment. It is a correspondence table between zones and MAP levels of the second gaming machine according to the present embodiment. It is a correspondence table between the MAP level and the winning rate of the pseudo bonus of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 0 (table A) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 0 (table B) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 0 (table C) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 0 (table D) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 0 (table E) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 1 (table A) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 1 (table B) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 1 (table C) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 1 (table D) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 1 (table E) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 2 (table A) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 2 (table B) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 2 (table C) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 2 (table D) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 2 (table E) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 3 (table A) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 3 (table B) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 3 (table C) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 3 (table D) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 3 (table E) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 4 (table A) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 4 (table B) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 4 (table C) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 4 (table D) of the second gaming machine according to the present embodiment. It is a diagram showing the normal map lottery table_zone 4 (table E) of the second gaming machine according to the present embodiment. It is a diagram showing a consecutive zone map lottery table (table F) of the second gaming machine according to the present embodiment. It is a diagram showing a continuous zone map lottery table (table G) of the second gaming machine according to the present embodiment. It is a diagram showing a continuous zone map lottery table (table H) of the second gaming machine according to the present embodiment. It is a diagram showing a consecutive zone map lottery table (Table I) of the second gaming machine according to the present embodiment. It is a diagram showing a map 0 o'clock forced portent entry lottery table of the second gaming machine according to the present embodiment. It is a diagram showing a forced precursor G number lottery table of the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table (MAP level 0) when the forced precursor G number is reached in the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table (MAP level 1) when the forced precursor G number is reached in the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table (MAP level 2) when the forced precursor G number is reached in the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table (MAP level 3) when the number of forced precursor Gs is reached in the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table (MAP level 4) when the number of forced precursor Gs is reached in the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table (MAP level 5) when the number of forced precursor Gs is reached in the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table (MAP level 6) when the forced precursor G number is reached in the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (no table type) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 0) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 1) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 2) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 3) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 4) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 5) of the second gaming machine according to the present embodiment. It is a diagram showing a normal AT lottery table (MAP level 6) of the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table when AT points are reached in the second gaming machine according to the present embodiment. It is a diagram showing an AT lottery table during fake signs of the second gaming machine according to the present embodiment. It is a diagram showing an AT type promotion lottery table (REG) during the present omen of the second gaming machine according to the present embodiment. It is a diagram showing an AT type promotion lottery table (BIG) during the main sign of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (continuous chance zone) of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (200G and later) of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (at the time of special ON) of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (1-100G) of the second gaming machine according to the present embodiment. It is a diagram showing an AT type lottery table (101-200G) of the second gaming machine according to the present embodiment. It is a figure which shows the AT type lottery table (normal) at the time of the middle stage cherry of the 2nd gaming machine based on this embodiment. It is a figure showing the AT type lottery table (continuous chance zone) at the time of the middle stage cherry of the second gaming machine according to the present embodiment. It is a diagram explaining a normal production pattern of the second gaming machine according to the present embodiment. It is a figure explaining the performance pattern when winning the Cherry Navi lottery of the second gaming machine according to the present embodiment. It is a simplified diagram for explaining the timing of state transition processing of the second gaming machine according to the present embodiment. It is a diagram showing a special rewritten lottery table (special OFF) of the second gaming machine according to the present embodiment. It is a diagram showing a special rewritten lottery table (special ON) of the second gaming machine according to the present embodiment. It is a diagram showing the CherryNavi lottery table (special OFF) of the second gaming machine according to the present embodiment. It is a diagram showing the CherryNavi lottery table (special ON) of the second gaming machine according to the present embodiment. It is a block diagram showing the structure of the control system of the third gaming machine according to the present embodiment. It is a diagram showing an example of the configuration of an information display device used when the third gaming machine according to the present embodiment is a normal (non-medalless) gaming machine. It is a diagram showing an example of the configuration of an information display device used when the third gaming machine according to the present embodiment is a medalless gaming machine. It is a block diagram showing the internal configuration of the HB-LSI used in the third gaming machine according to the present embodiment. FIG. 3 is a block diagram showing the internal configuration of an HB-LSI asynchronous serial communication circuit used in the third gaming machine according to the present embodiment. It is a diagram showing the contents of information set in the status register T and status register R provided in the status monitoring circuit in the asynchronous serial communication circuit of the third gaming machine according to the present embodiment. It is a block diagram showing the internal configuration of an HB-LSI random number generation circuit used in the third gaming machine according to the present embodiment. It is a block diagram showing the internal configuration of the main control board of the third gaming machine according to the present embodiment. It is a block diagram showing the internal configuration of the drum device board of the third gaming machine according to the present embodiment. It is a block diagram showing the internal configuration of the door relay board of the third gaming machine according to the present embodiment. It is a block diagram showing the internal configuration of the sub-control unit of the third gaming machine according to the present embodiment. It is a figure which shows the transmission mode of the command data between the main control part and sub-control part of the 3rd gaming machine based on this embodiment. It is a figure which shows the modification of the transmission mode of command data between the main control part and sub-control part of the 3rd gaming machine based on this embodiment. In the third gaming machine according to the present embodiment, it is a diagram showing a configuration example of command data transmitted from the main control section to the sub control section. FIG. 7 is a diagram for explaining an overview of DLE control performed on command data transmitted from the main control section to the sub control section in the third gaming machine according to the present embodiment. In the third gaming machine according to the present embodiment, it is a diagram showing a configuration example of command data when DLE control is not performed on command data transmitted from the main control unit to the sub control unit. In the third gaming machine according to the present embodiment, it is a diagram showing an example of the structure of command data when DLE control is performed on command data transmitted from the main control section to the sub control section. It is a flowchart showing an example of a communication data storage process executed by a main control unit of a conventional gaming machine. It is a flowchart which shows Example 1 of the communication data storage process performed by the main control part of the 3rd gaming machine based on this embodiment. It is a flowchart which shows Example 2 of the communication data storage process performed by the main control part of the 3rd gaming machine based on this embodiment. FIG. 7 is a diagram showing a first example of the configuration of data transmitted between boards in the main control unit in the third gaming machine according to the present embodiment. FIG. 7 is a diagram showing a second configuration example of data transmitted between boards in the main control unit in the third gaming machine according to the present embodiment.

Hereinafter, a gaming machine according to the present embodiment will be described with reference to the drawings. In this embodiment, a pachi-slot machine will be described as an example of a gaming machine.

[1. Pachislot machine structure]
First, the structure of the pachi-slot machine 1 will be explained with reference to FIGS. 1 and 2. Note that FIG. 1 is a diagram showing the external structure of the pachi-slot machine 1, and FIG. 2 is a diagram showing the internal structure of the pachi-slot machine 1. Further, for convenience of explanation, in the following explanation of the external structure, a part of the internal structure may be explained, and in the explanation of the internal structure, a part of the external structure may be explained.

[1-1. External structure]
[1-1-1. Housing]
The pachi-slot machine 1 includes a housing 2 in the shape of a rectangular box. The housing 2 also includes a metal cabinet G having a rectangular opening on the front side as the gaming machine main body, an upper door mechanism UD placed at the upper front of the cabinet G, and an upper door mechanism UD placed at the lower front of the cabinet G. It has a lower door mechanism DD.

The cabinet G has an intermediate support plate G1, a pair of left and right side walls G2, a back wall G3, a top wall G4, and a bottom wall G5. Note that in FIGS. 1 and 2, illustration of the rear wall G3 and the bottom wall G5 is omitted. Furthermore, two openings G4a are formed in the top wall G4 of the cabinet G, spaced apart from each other by a predetermined distance in the left-right direction, and penetrating in the vertical direction. A wooden plate member G4b is attached to the top wall G4 so as to close each of the two openings G4a.

Note that the plate member G4b is used to fix the pachislot machine 1 to a game island (not shown) when it is installed in a game parlor, but as long as such a fixing method is secured, metal or resin materials can be used. Alternatively, it can be formed integrally with the upper wall G4. Furthermore, as long as a certain level of strength is ensured for the cabinet G, a part or all of each component may be made of wood or resin.

Furthermore, inside the cabinet G, an upper opening G101 that opens forward is formed on the upper side across the intermediate support plate G1, and a lower opening G101 that opens forward is formed on the lower side across the intermediate support plate G1. A side opening G102 is formed. That is, the inside of the cabinet G is partitioned into an upper space and a lower space with the intermediate support plate G1 in between, and the intermediate support plate G1 functions as a partition plate that partitions the inside of the cabinet G into the upper space and the lower space. There is. The upper space is a space on the rear side of the upper door mechanism UD in the cabinet G, and houses a main display device 210, which will be described later, and the like. Further, the lower space is a space on the rear side of the lower door mechanism DD in the cabinet G, and accommodates a reel unit RU, a main control board 71, etc., which will be described later.

Note that the cabinet G does not necessarily need to be configured to include the intermediate support plate G1. That is, as long as each device etc. is appropriately accommodated within the cabinet G, a configuration may be adopted in which the upper space and the lower space are not partitioned. Moreover, the cabinet G can be simply called a "box body" or a "main body", and since it functions as a frame body that supports or fixes the upper door mechanism UD and the lower door mechanism DD, it can also be referred to as a "body frame", It can also be referred to as a "support body", "support frame", or "fixed frame".

[1-1-2. Front door]
The upper door mechanism UD and the lower door mechanism DD are formed to correspond to the shape and size of the opening of the cabinet G, and are provided so as to be able to close the upper space and the lower space of the opening in the cabinet G. That is, the upper door mechanism UD and the lower door mechanism DD function as a front door provided on the front side of the pachi-slot machine 1.

Further, each of the upper door mechanism UD and the lower door mechanism DD is attached to the cabinet G so as to be openable and closable, for example, by an opening/closing mechanism (not shown) such as a hinge provided on the left side wall G2. Note that either one of the upper door mechanism UD and the lower door mechanism DD is configured to be able to be opened and closed by the above-mentioned opening/closing mechanism, and the other is configured to be detachable only when one of the door mechanisms is in an open state. You can also do that.

The upper door mechanism UD has an effect display window UD1 provided in the center thereof, and an upper lamp 23 provided above the effect display window UD1. The effect display window UD1 is configured, for example, as a transparent panel made of resin, and allows visual confirmation of an effect image displayed on a screen device C that constitutes a main display device 210, which will be described later, provided on the back side of the effect display window UD1. In addition, in this embodiment, the main display device 210 that displays effects via the effect display window UD1 may be described as the main effect display section 21.

The lower door mechanism DD has a main display window 4 provided approximately at the center of the upper part thereof, and a reel unit RU attached to the inside of the cabinet G on the back side of the main display window 4. There is.

The reel unit RU is mainly composed of three reels 3L (left reel), 3C (middle reel), and 3R (right reel). Each reel 3L, 3C, 3R is composed of, for example, a cylindrical reel body and a translucent reel band attached to the circumferential surface of the reel body. symbols) are drawn at predetermined intervals along the rotation direction of the reels. Further, the reels 3L, 3C, and 3R are arranged in parallel (in a horizontal row) so that each reel can rotate at a constant speed in the vertical direction. The main display window 4 is configured as a transparent panel made of resin, for example, and allows at least some (for example, three) of the symbols on the circumferential surface of each reel 3L, 3C, and 3R to be visually recognized. Furthermore, inside each reel 3L, 3C, and 3R, a light source (a reel lamp included in lamps and LEDs to be described later) is provided at least at a position where the symbols are visible from the main display window 4, and at least each reel 3L, When 3C and 3R are rotating, they are illuminated from inside with a constant brightness to ensure the visibility of the symbols.

Further, the lower door mechanism DD has a sub effect display section 22 provided on the left side of the main display window 4, and a effect button 10b provided on the right side of the main display window 4. The sub effect display section 22 displays an effect image displayed on a sub display device 220, which will be described later. Note that the sub effect display section 22 can be configured as a touch panel, and can function not only as a function of displaying effects but also as one of the buttons for effects. The performance button 10b is an operation unit that receives a performance operation (performance operation) from the player.

In addition, the lower door mechanism DD is provided in the substantially horizontal pedestal portion formed below the main display window 4, with the MAX bet button 6a, 1 bet button 6b, and settlement button 9 provided on the left side, and the settlement button 9 provided approximately in the center. It has a presentation button 10a and a medal slot 5 provided on the right side.

The MAX bet button 6a and 1 bet button 6b are used to perform game operations (bet operations) by the player to use medals deposited (credited) inside the Pachislot machine 1. This is the operation section that accepts the commands (which can also be referred to as "", etc.). When the MAX bet button 6a is operated, if the current bet number is less than the maximum bet number (for example, 3 medals) and the number of medals credited is greater than the difference, the maximum bet number of medals will be bet. Ru. On the other hand, if the number of credited medals is less than the difference, no medals are bet. Further, when the 1 bet button 6b is operated, if the current bet number is less than the maximum bet number and there is one or more credited medals, one medal is bet.

The payment button 9 is an operation unit that accepts a game operation (payment operation) by the player to return (payment) the credited medals. In addition, if the payment button 9 is operated when there are no medals credited, the credit for the medals to be inserted or paid out is within the creditable number (for example, 50 medals). It may also be possible to accept a player's gaming operation (C/P mode selection operation) to enable selection of either mode (C mode) or pay mode (P mode) in which the medals are not credited. That is, the payment button 9 can also function as a so-called C/P button. The performance button 10a is an operation unit that receives a performance operation (performance operation) from the player.

The medal slot 5 receives medals inserted into the pachi-slot machine 1 from the outside by a player. The accepted medal is detected by a selector 31, which will be described later, and it is determined whether or not it is an appropriate medal. If one of the accepted medals is not proper, the accepted medal is returned from the medal payout port 11, which will be described later. Furthermore, if the accepted one medal is a proper one and the current number of bets is less than the maximum number of bets, one medal is bet. If the current bet number is the maximum bet number and the number of credited medals has not reached the creditable number, one medal is credited. On the other hand, if the number of credited medals has reached the creditable number, the accepted medals are returned from the medal payout port 11, which will be described later.

Further, the lower door mechanism DD has an information display device 14 provided between the main display window 4 and the above-mentioned pedestal. The information display device 14 includes a plurality of lamps (LEDs) and 7-segment LEDs, and displays information regarding the game depending on the lighting mode thereof.

In addition, the lower door mechanism DD includes a start lever 7 provided on the left side below the pedestal, three stop buttons 8L, 8C, 8R provided approximately in the center, and a start lever 7 provided on the right side. It has a locking mechanism 15. The start lever 7 is an operation section that is attached to be tiltable within a predetermined angle range and receives a game operation (start operation) from the player to start the game. Each stop button 8L, 8C, 8R is provided corresponding to each reel 3L, 3C, 3R, and is an operation section that accepts a game operation (stop operation) by a player to stop the rotation of each reel.

The locking mechanism 15 is composed of, for example, a key cylinder lock, and when the lower door mechanism DD is in a closed state, an administrator of the game parlor (for example, a clerk of the game parlor, etc.; the same applies hereinafter) inserts a door key (not shown) into the keyhole. ) is inserted and turned to the right to unlock, and the lower door mechanism DD becomes open. Note that the locking mechanism 15 may have not only the function of managing the opening and closing of the door mechanism but also the function of a reset switch. For example, if the manager of the game parlor inserts a door key into the keyhole and turns it counterclockwise, it may be possible to detect a reset operation similar to the reset switch 53 described later. Further, in this embodiment, when the lower door mechanism DD is in the open state, the upper door mechanism UD can also be configured to be in the open state in conjunction with this, and the lock corresponding to the upper door mechanism UD can be It is also possible to provide separate mechanisms so that opening and closing can be managed independently.

The lower door mechanism DD also includes a waist panel 13 provided at the center of the lower part, a medal tray 12 provided below the waist panel 13, and a medal payout port 11 provided above the medal tray 12. , sound-transmitting holes 24a and 24b provided on the left and right sides of the medal payout opening 11.

The waist panel 13 includes, for example, a decorative panel on which model information such as a logo representing the model name or a character representing a motif is drawn, and a light source (such as a lamp or LED described later) for illuminating this decorative panel from the back side. Consists of a lumbar lamp (included). The medal receiver 12 stores medals paid out from the medal payout port 11. The medal payout port 11 discharges medals paid out (or returned) from the inside of the pachi-slot machine 1 to the outside. Note that the medals discharged from the medal dispensing port 11 include those dispensed from a hopper device 32 (described later) and those returned from a selector 31 (described later) through a cancel chute (not shown). The sound transmission holes 24a and 24b are located on the back side of each of the speakers 35a and 35b (the symbol of the speaker 35a is omitted in FIG. 2) installed on the inside of the cabinet G to output sounds such as sound effects and BGM. is transmitted toward the front side of the pachi-slot machine 1.

Note that in this embodiment, an upper door mechanism UD and a lower door mechanism DD are provided in response to the fact that the inside of the cabinet G is partitioned into an upper space and a lower space. As long as it can be opened and closed, it can be constructed as a single door mechanism or as three or more door mechanisms. Moreover, it can also be configured as a double door mechanism (for example, an outer door and an inner door) in the front-rear direction. In addition, the upper door mechanism UD and the lower door mechanism DD can also be simply referred to as a "door" or "door", and since they function as members that can open and close the opening in the cabinet G, they can be referred to as "opening/closing members" or "doors". It can also be referred to as a "door member" or a "door member."

[1-1-3. Fluctuation display]
As described above, the pachi-slot machine 1 includes the reels 3L, 3C, 3R and the main display window 4. Each of the reels 3L, 3C, and 3R starts rotating when the start lever 7 is operated (when the player performs a start operation), driving and controlling stepping motors 51L, 51C, and 51R, which will be described later. As a result, the symbols displayed on the main display window 4 are displayed in a variable manner. Furthermore, when each stop button 8L, 8C, 8R is operated (when a stop operation is performed by the player), stepping motors 51L, 51C, 51R, which will be described later, are drive-controlled for each reel 3L, 3C, 3R. This stops each rotation. As a result, the symbols displayed on the main display window 4 are stopped and displayed.

That is, each reel 3L, 3C, 3R and the main display window 4 are variable display units (means) that can variably display (and stop display) a plurality of symbols in multiple rows, or variably display (and stop display) a plurality of symbols. ) configuring a plurality of possible variable display units (means). Note that the variable display section (means) can also be referred to as a "symbol display section (means)", a "variable display section (means)", etc. Further, the symbols can be referred to as "pictures", "patterns", etc., and can also be referred to as "identification information" in that sense, since any information that can be visually identified by the player is sufficient.

Further, the main display window 4 is configured such that when the rotation of each reel 3L, 3C, 3R is stopped, three consecutively arranged symbols for each reel are displayed within its frame. That is, the main display window 4 displays one symbol in each of the upper, middle, and lower regions of each column (3 symbols in total) (3 rows x 3 columns within the frame of the main display window 4). (The design is displayed in this manner.) Note that the main display window 4 is sometimes referred to as a "symbol display area" or a "window section."

Furthermore, an effective line is defined in the main display window 4. The valid line is a line for determining whether or not a prescribed combination of symbols has been displayed when symbols in all rows have been stopped and displayed in response to a stop operation by the player. In this sense, the active line can also be referred to as a "winning line", a "judgment line", etc. Further, the effective line is configured as a line that connects any one of the regions in each column. That is, when the main display window 4 is configured to display symbols in a manner of 3 rows x 3 columns, it is possible to define a maximum of 27 valid lines. However, in reality, one or more of the lines can be defined as valid lines, and the other lines can be defined as invalid lines that are not valid lines.

For example, the line connecting the middle area of the reel 3L, the middle area of the reel 3C, and the middle area of the reel 3R is the "center line," and the line connecting the middle area of the reel 3L, the top area of the reel 3C, and the top area of the reel 3R is the "center line." The connecting line is the "top line", the line connecting the lower area of reel 3L, the lower area of reel 3C, and the lower area of reel 3R is the "bottom line", the lower area of reel 3L, the middle area of reel 3C, and the reel 3R. The line that connects the upper area is called a "cross-up line," and the line that connects the upper area of reel 3L, the middle area of reel 3C, and the lower area of reel 3R is called a "cross-down line." Since the line connects each region in a straight line, one or more of these lines are often defined as the effective line. However, as described above, a so-called irregular line that connects each area of each column with a polygonal line can also be defined as an effective line.

In addition, in order for the active line to be activated, the medals required for the current game (the number of medals available for starting the game) must be bet before the player starts the operation. The number of active lines displayed may be the same regardless of the number of bets, or may vary depending on the number of bets. For example, if the three lines mentioned above are defined as the "center line", "top line", and "bottom line", then in the case of the former, the number of bets is either 1 to 3. ``Centerline'', ``Topline'', and ``Bottomline'' are enabled even if On the other hand, in the latter case, if the number of bets is 1, only the "center line" will be activated, if the number of bets is 2, the "center line" and "top line" will be activated, and if the number of bets is 3 (maximum bet number), the "center line", "top line", and "bottom line" are enabled.

In addition, in this embodiment, the variable display section has three reels 3L, 3C, and 3R, and a main display window 4 that can display three symbols in each column, so that 3 rows x 3 Although the symbols are displayed in a column format, the symbol display format in the variable display section is not limited to this. For example, the number of reels is 1, 2, or 4 or more, and the number of symbols displayed in each row is 1, 2, or 4 or more. You can also display the design with . Furthermore, in this case, the number of definable effective lines is also increased or decreased as appropriate.

Furthermore, in the present embodiment, the variable display section displays the symbols in a variable manner by rotating the reels 3L, 3C, and 3R, but the configuration of the variable display section is not limited to this. For example, it may be configured using an image display device similar to the main display device 210 and sub display device 220 described later, or it may be configured using other display devices (for example, organic EL or 7-segment LED). . Alternatively, for example, a configuration using other physical devices (eg, a belt, etc.) may be used. Further, the arrangement, size, etc. of the variable display section can be changed as appropriate.

Further, in this embodiment, the variable display section functions as a main side display section directly related to the game, which is controlled by the main control circuit 100 described below. A variable display section may be provided as a sub-display section that is controlled by a sub-display section that is related to performances that are not directly related to games. Note that the sub-side display section can be configured using, for example, the main display device 210 and the sub-display device 220. In other words, a variable display section that displays symbols in a variable manner in response to a player's start operation (or other start conditions are met), and that stops and displays symbols in response to a player's stop operation (or other stop conditions are met). In addition to the main side display section, a sub side display section may also be provided. In this case, in order for the player to be able to identify whether the variable display section is directly related to the game or not, the words "Kyokudou" or "Main Reel" are displayed near the main side display section. It is sufficient to attach an identification display in which is displayed to make it possible to identify that the variable display section is the main display section. Note that such an identification display may be displayed on the main display device 210 or the sub display device 220.

[1-1-4. Medal slot]
As described above, the pachi-slot machine 1 includes the medal slot 5 that receives medals inserted into the pachi-slot machine 1 from the outside by a player. Note that the medal slot 5 and the selector 31 (to be described later) have the function of betting the number of medals required for one game, similar to the MAX bet button 6a and the 1 bet button 6b, so such an insertion operation is , for example, can also be referred to as a bet operation. Therefore, it can be said that the medal slot 5 is a bet operation detection unit (means) that can detect the player's bet operation. Note that the shape, arrangement, size, etc. of the medal slot can be changed as appropriate. Furthermore, if the pachi-slot machine 1 is configured as a medalless gaming machine, which will be described later, this configuration is not necessarily essential.

In addition, in this embodiment, the use of medals as game media is explained as an example of the game value used in the game or given according to the game result, but the game value used in this way is It is not limited to this. For example, coins, game balls, point data for games, tokens, etc. can also be used. Further, the gaming value can also be simply referred to as "value" or "gaming value".

[1-1-5. Operation section]
The pachi-slot machine 1 includes, for example, the following operating sections as operating sections that can be operated by a player. Note that each operation section shown below is just an example, and the configuration may include a different operation section, or the configuration may not include operation sections that are not necessarily essential. .

[1-1-5-1. Bet button]
As described above, the pachi-slot machine 1 includes a MAX bet button 6a and a 1 bet button 6b that accept a bet operation by a player to use medals deposited (credited) therein. Further, such a bet operation is detected by a bet switch 6S, which will be described later. Therefore, the MAX bet button 6a, the 1 bet button 6b, and the bet switch 6S constitute a bet operation detection unit (means) that can detect the player's bet operation. Note that the bet button only needs to be able to detect the player's bet operation, and its shape, arrangement, size, etc. can be changed as appropriate. Further, in this embodiment, the MAX bet button 6a and the 1 bet button 6b are provided, but only the MAX bet button 6a may be provided without providing the 1 bet button 6b. Further, a 2-bet button for betting two medals may be provided separately.

[1-1-5-2. Start lever]
As described above, the pachi-slot machine 1 includes the start lever 7 that accepts a player's start operation to start the game. Further, such a start operation is detected by a start switch 7S, which will be described later. Therefore, the start lever 7 and the start switch 7S constitute a start operation detection section (means) that can detect the player's start operation. Note that the start lever only needs to be able to detect the player's starting operation, and its shape, arrangement, size, etc. can be changed as appropriate.

[1-1-5-3. Stop button]
As described above, the pachi-slot machine 1 includes stop buttons 8L, 8C, and 8R, which are provided corresponding to the respective reels 3L, 3C, and 3R, and which accept a stop operation by a player to stop the rotation of each reel. Further, such a start operation is detected by a stop switch 8S, which will be described later. Therefore, each stop button 8L, 8C, 8R and stop switch 8S constitute a stop operation detection unit (means) capable of detecting a stop operation by a player. Note that the stop button only needs to be able to detect the player's stop operation, and its shape, arrangement, size, etc. can be changed as appropriate.

[1-1-5-4. Payment button]
As described above, the pachi-slot machine 1 includes the settlement button 9 that accepts the player's settlement operation (return operation) to return (settlement) the credited medals. Further, such a payment operation is detected by a payment switch 9S, which will be described later. Therefore, the payment button 9 and the payment switch 9S constitute a payment operation detection unit (means) that can detect the payment operation by the player. Note that the payment button only needs to be able to detect the player's payment operation, and its shape, arrangement, size, etc. can be changed as appropriate.

[1-1-5-5. Performance button]
As described above, the pachi-slot machine 1 includes performance buttons 10a and 10b that accept performance operations from the player. Note that such presentation operations are detected by detection switches (not shown) provided corresponding to the respective presentation buttons. Therefore, the performance buttons 10a, 10b and the detection switch constitute a performance operation detection unit (means) capable of detecting the performance operation of the player. It should be noted that the effect button only needs to be able to detect the player's effect operation, and its shape, arrangement, size, etc. can be changed as appropriate. Further, in this embodiment, two effect buttons 10a and 10b are provided, but it is also possible to configure the system without providing either of them, or to provide only one of them. can. Moreover, it is also possible to configure so that three or more presentation buttons are provided.

The main uses of the presentation buttons include changing the presentation mode when executing a specific presentation (for example, operation-linked presentation described below), and performing selection/decision operations in the user menu described below. Therefore, it is also possible to configure so that buttons for effects are provided depending on the purpose. For example, it is assumed that the presentation buttons 10a and 10b are used for the former purpose, and the above-mentioned touch panel may be used for the latter purpose. Note that for use in the latter purpose, it is also possible to provide a jog dial, a cross key, or the like that can accept selection/decision operations as another presentation button.

[1-1-6. Medal payout port]
As described above, the pachi-slot machine 1 includes the medal payout port 11 for discharging medals paid out (or returned) from the inside of the pachi-slot machine 1 to the outside. In addition, when a winning occurs and medals are paid out, the medal payout port 11 is for giving the player the medals paid out from the hopper device 32, which will be described later. It can also be said that it is part of the means. Further, the shape, arrangement, size, etc. of the medal payout port can be changed as appropriate. Furthermore, if the pachi-slot machine 1 is configured as a medalless gaming machine, which will be described later, this configuration is not necessarily essential.

[1-1-7. Medal saucer]
As described above, the pachi-slot machine 1 includes the medal tray 12 that stores medals paid out from the medal payout port 11. That is, the medal tray 12 constitutes a storage section (means) that can store the awarded game value. Note that the shape, arrangement, size, etc. of the medal tray can be changed as appropriate. Furthermore, if the pachi-slot machine 1 is configured as a medalless gaming machine, which will be described later, this configuration is not necessarily essential.

[1-1-8. Waist panel]
As described above, the pachi-slot machine 1 includes a waist panel 13 that includes, for example, a decorative panel on which model information is drawn and a waist lamp for illuminating the decorative panel from the back side. The waist panel 13 basically shows the type of pachislot machine 1 in an easy-to-understand manner to the player, but for example, the waist panel 13 itself can be By configuring it with an image display device or the like, it can be configured as one of the performance execution means that can execute the performance.

[1-1-9. Information display]
As described above, the pachi-slot machine 1 includes the information display device 14 that displays information regarding the game depending on the lighting mode. That is, the information display device 14 constitutes an information display section (means) that can display information regarding games.

The information display device 14 includes, for example, an insert lamp, a start lamp, a replay lamp, a bet number lamp, a credit lamp, a payout number lamp, an instruction monitor, a limit lamp, and the like.

The insert lamp indicates that medals can be inserted by lighting up. By lighting up, the start lamp indicates that the game can be started in conjunction with the operation of the start lever 7. When lit, the replay lamp indicates that medals have been automatically inserted due to the replay operation. The bet number lamp lights up to display the number of medals bet. The credit lamp displays the number of credited medals depending on the lighting mode. The number of payout lamps display the number of medals (number of payouts) that have been paid out according to game results depending on the lighting mode.

Further, the instruction monitor includes a notification lamp (stop operation display section) and a section lamp (status display section). The notification lamp lights up in a manner that uniquely corresponds to the information on the stop operation to be notified in a situation where the player is notified of the information on the stop operation (for example, in an AT state), thereby providing information on the stop operation. Display. Note that "an aspect that uniquely corresponds to the information of the stop operation to be notified" refers to, for example, the press order (in this embodiment, this may be referred to as "batting order"), "1st (the first stop operation When notifying the press order "2nd (performing the first stop operation on reel 3C)", display the numerical value "1" on the instruction monitor. The number "2" is displayed on the instruction monitor, and when the push order "3rd (performing the first stop operation on reel 3R)" is notified, the number "3" is displayed on the instruction monitor. It is about. Note that the notification lamp does not necessarily have to be provided separately from the credit lamp and the payout number lamp. For example, information on the stop operation may be displayed using either a credit lamp or a payout number lamp.

In this way, in the present embodiment, in a situation where information on a stop operation is notified to the player, the sub-side notification means (for example, the main performance display section 21) controlled by the sub-control circuit 200, which will be described later, In addition, information on the stop operation is also notified by an instruction monitor as a main notification means controlled by the main control circuit 100, which will be described later. Note that the mode of notification in the main side notification means and the mode of notification in the sub-side notification means may be different from each other. That is, the main-side notification means only needs to notify in a manner that uniquely corresponds to the information on the stop operation to be notified, and does not necessarily need to directly notify the information on the stop operation. For example, when notifying the push order "1st", even if the numerical value "1" is displayed on the instruction monitor, some players may not be able to specify the content of the notification. On the other hand, the sub-side notification means may directly notify information about the stop operation. For example, when notifying the push order "1st", the main effect display section 21 may directly notify instruction information for causing the reels 3L to perform the first stop operation.

Further, the section lamp, when lit, indicates that the current state is in an advantageous section, which will be described later. For example, when transitioning from a non-advantageous section to an advantageous section (described later), the section lamp lights up at any timing until the start of the game in the advantageous section, and then when the advantageous section ends and the game shifts to the non-advantageous section. In this case, the light is turned off at an arbitrary timing until the game in the non-advantageous section is started. Note that the lighting timing of the section lamps is not limited to this. For example, when first transitioning from a non-advantageous section or an advantageous section (normally advantageous section) to an increased section (AT state) described below in an advantageous section, any arbitrary period until the game in the increased section starts. It may also be something that lights up at the right time. In other words, the section lamp may indicate that the section is in an advantageous section, regardless of whether it is a production section or an increase section, or at least an advantageous section including this from the start of the first increase section. It may also be possible to report the period until the end of the period.

Further, the limit lamp indicates that a limit process, which will be described later, has been executed or the possibility thereof, depending on its lighting mode. For example, when the limit process is executed, the light is turned on to notify the player that the advantageous state (for example, the AT state) has been forcibly terminated by the execution of the limit process. Further, for example, when the limit process is about to be executed, the light blinks to indicate that there is a high possibility that the advantageous state will be forcibly terminated by the limit process. In addition, other information related to the limit process can be reported as appropriate by providing other triggers for turning on, blinking, or turning off the light.

[1-1-10. Performance display]
As described above, the pachi-slot machine 1 includes the main effect display section 21 and the sub-effect display section 22 that display effect images. The main performance display section 21 and the sub-performance display section 22 constitute a performance display section (means) capable of displaying a performance. Moreover, it is configured as one of the performance execution means that can perform a performance from a visual viewpoint to the player.

The main performance display section 21 includes a main display device 210 that displays a performance via the performance display window UD1. The main display device 210 also includes a display unit A that is replaceably mounted on an intermediate support plate G1 in the cabinet G, an irradiation unit B that emits irradiation light for image display, and an irradiation unit B that emits irradiation light for image display. It is configured as a so-called projection mapping device having a screen device C that makes an image appear by being irradiated with light. In this embodiment, by configuring the main display device 210 in this way, sophisticated and powerful effect display is possible, but the configuration of the main display device 210 is not limited to this. In other words, it is sufficient if it is possible to provide a visual effect to the player, and it may be configured as an image display device such as a liquid crystal display device, an organic EL device, a 7-segment LED device, etc., or a display device such as a sub-reel, etc. It can also be configured as a variable display device or a dot display device. Further, from this point of view, the shape, arrangement, size, etc. can be changed as appropriate. Furthermore, in the case where the pachi-slot machine 1 is mainly designed to provide entertainment based on so-called rolls, the main effect display section 21 may not be provided (sub-effect display section 22 as well).

The sub effect display section 22 is configured to include a sub display device 220. Further, the sub display device 220 is configured as a liquid crystal display device. Note that, like the main display device 210, the sub display device 220 can also be configured as another image display device or a display device, or can be configured as a variable display device or a dot display device. Further, from this point of view, the shape, arrangement, size, etc. can be changed as appropriate. In addition, since the main performance display section 21 is configured with a large screen, it mainly displays performances closely related to the current game, such as push order notification, winning notification, continuous performance, etc., and the sub performance display section 22 is composed of a small screen, so it is possible to display the display contents separately depending on the purpose, such as mainly displaying effects that are not closely related to the current game, such as game history etc. It is possible. In addition, in this embodiment, the main effect display section 21 and the sub effect display section 22 are configured to be provided, but it is also possible to configure without providing either of these sections. It is also possible to configure so that only one of them is provided. Moreover, it is also possible to configure so that three or more effect display sections are provided.

[1-1-11. lamp]
As mentioned above, the pachi-slot machine 1, like the upper lamp 23 mentioned as an example, has a light emission mode (not only lighting, flashing, or turning off, but also the brightness and color of the light when configured as a full-color LED). ) is equipped with one or more lamps (light emitting means) that can perform effects. Moreover, such a light emitting means is configured as one of the performance execution means that can perform a performance from a visual viewpoint to the player. In addition, from such a viewpoint, the number, shape, arrangement, size, etc. can be changed as appropriate.

Other lamps included in the lamps and LEDs described below include, for example, side lamps provided on both end surfaces of the upper door mechanism UD and both end surfaces of the lower door mechanism DD, and operation sections provided in each operation section. Examples include lamps and the like. Note that the latter includes a function that informs the player whether or not each operation part can be operated, so when such a function is activated, the light emission mode does not change depending on the content of the performance. , it can be controlled to emit light in a unique light emission mode.

[1-1-12. Speaker]
As described above, the pachi-slot machine 1 includes speakers 35a and 35b that output sounds such as sound effects and BGM. The speakers 35a and 35b constitute audio output means that can produce effects by outputting audio. Moreover, it is configured as one of the performance execution means that can perform a performance from an auditory viewpoint to the player. In addition, from such a viewpoint, the number, shape, arrangement, size, etc. can be changed as appropriate.

[1-1-13. Other production equipment]
Note that the pachi-slot machine 1 may be provided with production devices other than the various production devices (production execution means) described above. For example, it is possible to perform a performance by providing a performance device such as a movable performance device such as a so-called role model, a vibration performance device that performs a performance using vibration, or an air performance device that performs a performance by jetting air. In other words, a performance device that can execute a performance that appeals to any of the player's five senses (sight, hearing, touch, taste, smell) (allows the player to recognize that the performance is being performed). If so, you can use any of them. Therefore, in this embodiment, "performing a performance" means, unless otherwise specified, using any one or more of the above-mentioned various performance devices (direction execution means) to perform a performance. This indicates that it may be executed.

[1-2. Internal structure]
[1-2-1. selector]
The selector 31 (number omitted in FIG. 2) is a flow path for medals inserted from the medal slot 5, and is provided on the back side of the lower door mechanism DD. The selector 31 includes, for example, a medal sensor 31S, which will be described later, and a sorting device.

The medal sensor 31S detects a medal inserted from the medal slot 5 and determines whether the detected medal is an appropriate medal. When the medal sensor 31S determines that the detected medal is an appropriate medal and the medal is in a state where it can be accepted, the sorting device transfers the medal to the hopper device 32, which will be described later. The drive is controlled so that it is guided. Note that in this case, 1 is added to the number of bets or the number of credits. On the other hand, when the medal sensor 31S determines that the detected medal is not an appropriate medal, and when the medal cannot be accepted, the sorting device passes the medal through the cancellation chute to the medal payout port 11. The drive is controlled so that it is returned from. If an abnormality occurs in medal detection by the medal sensor 31S, a selector error occurs. In this case, if the reset operation is performed after the cause of the abnormality (for example, medal jam) is removed, the error state will be canceled.

That is, the selector 31 constitutes a game medium detection section (means) that can detect the inserted game medium. Further, the selector 31 constitutes a determining means capable of determining whether or not the inserted gaming medium is appropriate. Further, the selector 31 constitutes a distributing means that stores the inserted game media internally when it is appropriate, and discharges it to the outside when the inserted game medium is not appropriate. Furthermore, the configuration, arrangement, size, etc. of the selector 31 can be changed as appropriate. Furthermore, if the pachi-slot machine 1 is configured as a medalless gaming machine, which will be described later, this configuration is not necessarily essential.

[1-2-2. Hopper device]
The hopper device 32 is provided in the lower space within the cabinet G. The hopper device 32 includes, for example, a bucket section that stores medals inserted from the medal slot 5 and guided by the selector 31, and is provided at the bottom of the bucket section, and stirs the medals stored in the bucket section. It has a disk section that guides medals one by one to a discharging section, a discharging section that discharges medals guided by the disk section one by one, and a count sensor that counts the medals discharged from the discharging section.

The bucket section is configured to be able to store a certain number of medals. Medals exceeding a certain number are guided to a medal auxiliary storage 33, which will be described later, through a guide path provided on the top side. Note that when the medals stored in the bucket section become empty, a hopper empty error occurs. In this case, if a reset operation is performed after replenishing medals, the error state will be canceled.

The disk part has a plurality of medal-shaped hollow parts formed radially from the center, and when the central shaft is rotationally driven in accordance with a drive signal, the medals fitted in the hollow parts are guided one by one to the ejection part. Note that the medals stored in the bucket section are stirred by the rotation of the disk section. Further, if an abnormality occurs in the rotation of the disk unit, a hopper jam error occurs. In this case, if the reset operation is performed after the cause of the abnormality (for example, medal jam) is removed, the error state will be canceled.

The count sensor detects the medals discharged from the discharge section and counts the number of medals. For example, when dispensing one medal, the disc part starts rotating, and then stops rotating in response to the count sensor counting the dispensing of one medal. In this way, an appropriate number of medals are paid out.

That is, the hopper device 32 constitutes a game media payout unit (means) that can pay out game media. Further, as described above, it can be said that it is part of a privilege granting means that grants a privilege to a player. Further, the configuration, arrangement, size, etc. of the hopper device 32 can be changed as appropriate. Furthermore, if the pachi-slot machine 1 is configured as a medalless gaming machine, which will be described later, this configuration is not necessarily essential.

[1-2-3. Auxiliary medal storage]
The medal auxiliary storage 33 is provided in the lower space within the cabinet G. The medal auxiliary storage 33 includes, for example, a storage section that stores medals guided from the bucket section of the hopper device 32, and a medal auxiliary storage that is provided near the storage section and detects the capacity of medals stored in the storage section. It has a storage switch 33S.

The storage section is configured to be able to store a certain number of medals. If the medal auxiliary storage switch 33S determines that more than the certain number of medals have been stored, a medal auxiliary storage error occurs. In this case, if the reset operation is performed after reducing the number of medals stored in the storage unit to at least a certain number, the error state will be canceled.

That is, the medal auxiliary storage 33 constitutes a surplus game media storage section (means) that can store surplus game media. Note that the configuration, arrangement, size, etc. of the medal auxiliary storage 33 can be changed as appropriate. Furthermore, if the pachi-slot machine 1 is configured as a medalless gaming machine, which will be described later, this configuration is not necessarily essential.

[1-2-4. Power supply]
The power supply device 34 is provided in the lower space within the cabinet G. The power supply device 34 includes, for example, a power supply board 34a and a power switch 34b, and supplies power to the pachi-slot machine 1 when the power switch 34b is turned on. Note that the power supply device 34 converts the AC voltage 100V power supplied from the power cable (not shown) into the DC voltage power required by each part, and supplies the converted power to each part, similar to household electrical appliances. do. That is, the power supply device 34 constitutes a power supply unit (means) that can supply necessary power to the gaming machine. Note that the configuration, arrangement, size, etc. of the power supply device 34 can be changed as appropriate.

In addition, in this embodiment, the configuration is such that the setting key type switch 52 and the reset switch 53, which will be described later, are provided on the main control board 71 (more specifically, on the main control board case, which will be described later). It is also possible to configure the power supply device 34 to include a switch.

[1-2-5. substrate]
The pachi-slot machine 1 includes, for example, the following boards as necessary for various controls. Note that each of the substrates shown below is merely an example, and the structure may include a different substrate, or the structure may not include substrates that are not necessarily essential.

[1-2-5-1. Main control board]
The main control board 71 is attached to the back side of the reel unit RU within the cabinet G. The main control board 71 is a game control board that performs control related to games, and is located inside a resin main control board case (not shown) that is transparent (or nearly transparent) so that its status can be visually recognized. is housed in. The electrical configuration of the main control board 71 will be described later.

Note that there are various restrictions on the specifications of the main control board 71, and it is basically configured by DIP mounting various electronic components, but some or all of the various electronic components may be SMT mounted (surface mounting). It may also be configured by implementing (implementing). Further, in this case, a test point may be provided for checking the operation using a tester or an oscilloscope. Moreover, small electronic components not exceeding 6 mm2 may be used for some or all of the various electronic components. Further, the board surface of the main control board 71 may be configured to have multiple layers.

[1-2-5-2. Sub-control board]
The sub-control board 72 is attached within the cabinet G to the back side of the intermediate support plate G1. The sub-control board 72 is an effect control board that controls effects, and is housed in a sub-control board case (not shown) made of resin. Note that the sub-control board case can be constructed as a transparent (or nearly transparent) resin case like the main control board case, or it can be constructed of another material that is opaque (or nearly opaque). It can also be configured as a case using . The electrical configuration of the sub-control board 72 will be described later.

[1-2-5-3. Other boards]
(Main relay board)
The main relay board 73 (symbol omitted in FIG. 2) is installed at a specific position in the cabinet G (for example, on the back side of the lower door mechanism DD), and is connected to various devices connected to the main relay board 73 and the main controller. This is an intermediate control board for relaying between the board 71 and between the main control board 71 and the sub-control board 72. Note that the main relay board 73 is configured as a separate board from the main control board 71 for convenience of control efficiency and wiring efficiency, so all functions of the main relay board 73 can be controlled as the main control board unless there is a particular problem. It is also possible to have a configuration in which the main relay board 73 is not provided and is placed on the board 71. Further, from this point of view, the main relay board 73 may be further divided into a plurality of relay boards to improve control efficiency and wiring efficiency. That is, a plurality of boards may be provided as the main relay board.

(Sub relay board)
The sub-relay board 74 is attached to a specific position within the cabinet G (for example, on the back side of the lower door mechanism DD), and is installed between various devices connected to the sub-relay board 74 and the sub-control board 72, and This is an intermediate control board for relaying between the main control board 71 and the sub control board 72. Note that the sub-relay board 74 is configured as a separate board from the sub-control board 72 for convenience of control efficiency and wiring efficiency, so all functions of the sub-relay board 74 can be performed as a sub-control board if there is no particular problem. It is also possible to have a configuration in which the sub-relay board 74 is not provided and is placed on the board 72. Further, from this point of view, the sub relay board 74 may be further divided into a plurality of relay boards to improve control efficiency and wiring efficiency. That is, a plurality of substrates may be provided as sub-relay substrates.

(External centralized terminal board)
The external centralized terminal board 55 is installed at a specific position in the cabinet G (for example, on the back side of the lower space), and receives signals such as a medal input signal, a medal payout signal, external signals 1 to 4, and a security signal. Output to the outside of the pachislot machine 1. Note that the output start conditions and output end conditions of the external signals 1 to 4 can be set as appropriate, and the transition of the internal state of the pachi-slot machine 1 (for example, the bonus state or AT state) can be set externally according to the playability. It makes it possible to report. Since the external centralized terminal board 55 is usually connected to an external data display device or hall computer, these devices can be used to check not only the status of medal insertion and payout and the occurrence of errors in the pachislot machine 1. , it is possible to recognize such internal state transitions.

(Interface board for testing machine)
The first interface board 301 for the test machine and the second interface board 302 for the test machine are both relay boards used when outputting various signals related to the game to the test machine in the certification test (sight shooting test) of the pachi-slot machine 1. (Please note that the pachi-slot machine 1 as a release product for sale is not equipped with these relay boards, so the main control board 71 for sale includes the first interface board 301 for the test machine and the second interface board 301 for the test machine. Various electronic components required to connect to the interface board 302 are also not mounted). For example, test signals for controlling the main operations related to the game (e.g., internal lottery, reel stop control, etc.) are output via the first interface board 301 for the test machine, and are also determined by the main control board 71. Test signals and the like related to the pressed order navigation are outputted via the second interface board 302 for the testing machine.

[2. Electrical configuration of pachislot machine]
Next, with reference to FIG. 3, the electrical configuration of the pachi-slot machine 1 will be described. Note that FIG. 3 is a block diagram showing the electrical configuration of the pachi-slot machine 1.

As described above, the pachi-slot machine 1 includes a main control board 71, a sub-control board 72, a main relay board 73, and a sub-relay board 74. Main control board 71 and main relay board 73, main relay board 73 and sub-relay board 74, and sub-relay board 74 and sub-control board 72 are electrically connected, respectively. The main control board 71 and the sub-control board 72 are electrically connected to each other via the main relay board 73 and the sub-control board 74 so as to enable one-way serial communication from the main control board 71 to the sub-control board 72. connected.

A main control circuit 100 as a game control section that controls games is mounted on the main control board 71. The main control circuit 100 includes, for example, a main CPU 101, a main ROM 102, a main RAM 103, a clock pulse generation circuit (not shown), a random number circuit (not shown), and the like. The main ROM 102 stores various control programs executed by the main CPU 101, various data tables, data for transmitting various control instructions (commands) to the sub-control circuit 200, and the like. The main RAM 103 is provided with a storage area for storing various data such as internal winning combinations determined by execution of a control program. The clock pulse generation circuit generates a clock pulse signal for operating the main CPU 101. The random number circuit generates random numbers in a predetermined range (for example, 0 to 65535 or 0 to 255, etc.). The main CPU 101 executes various control programs based on the generated clock pulse signals. Furthermore, one or more values are extracted as random numbers from among the generated random numbers as necessary. In this way, control related to the overall gaming operation is performed.

A sub-control circuit 200 is mounted on the sub-control board 72 as an effect control section that controls effects. The sub control circuit 200 includes, for example, a sub CPU 201, a sub RAM 203, and the like. Further, a ROM cartridge board 202 is connected to the sub-control board 72. The ROM cartridge board 202 includes various control programs executed by the sub CPU 201, various data tables, and various presentation data (for example, video data and drive data related to the main display device 210, video data related to the sub display device 220, lamps, etc.). Lamp data related to the LED group, sound data related to the speaker group, etc.) are stored. The sub-RAM 203 includes a storage area for registering performance contents and various performance data determined by execution of a control program, a storage area for storing data related to various control commands (commands) transmitted from the main control board 71, etc. provided. Note that the random number value for the performance may be generated and extracted within the sub CPU 201 from random numbers in a predetermined range (for example, 0 to 32767, etc.), or the main control The generation and extraction may be performed by providing a random number circuit similar to the circuit 100. Alternatively, a sub-ROM may be included in the sub-control circuit 200 instead of the ROM cartridge board 202, and various control programs etc. may be stored in the sub-ROM. Further, the ROM cartridge board 202 may be configured to store various performance data, and the sub-ROM within the sub-control circuit 200 may be configured to store various control programs and various data tables. Further, the sub control circuit 200 includes a microprocessor (for example, also referred to as "VDP") dedicated to images, such as a GPU, which allows images to be displayed on the main display device 210 and the sub display device 220. It may be configured to generate (edit).

The main control board 71 includes stepping motors 51L, 51C, 51R, a setting key type switch 52, a reset switch 53, a role ratio monitor device 54, an external centralized terminal board 55, a hopper device 32, a medal auxiliary storage switch 33S, and a power supply. A device 34 is electrically connected. In addition, the main control board 71 is electrically connected to the door opening/closing monitoring switch 56, medal sensor 31S, bet switch 6S, start switch 7S, stop switch 8S, payment switch 9S, and information display device 14 via the main relay board 73. It is connected to the. Note that, if the first interface board 301 for a test machine and the second interface board 302 for a test machine are mounted, they are electrically connected to the main control board 71 via the main relay board 73, for example.

In addition, the external centralized terminal board 55, hopper device 32, medal auxiliary storage switch 33S, power supply device 34, medal sensor 31S, bet switch 6S, start switch 7S, stop switch 8S, payment switch 9S, information display device 14, testing machine Since the first interface board 301 for the test machine and the second interface board 302 for the test machine have already been explained, their explanation will be omitted here.

The stepping motors 51L, 51C, and 51R are connected to the reels 3L, 3C, and 3R via gears each having a predetermined reduction ratio, and are driven to rotate and stop the reels 3L, 3C, and 3R. Note that each reel 3L, 3C, 3R rotates at a constant angle each time one pulse is output to each stepping motor 51L, 51C, 51R, so the main CPU 101 controls each stepping motor 51L, 51R, The number of times a pulse is outputted to 51C and 51R is counted, and the symbol position of each reel 3L, 3C, and 3R is managed based on the count result. Furthermore, each reel 3L, 3C, and 3R is provided with a reel index (not shown) that determines the initial position for performing such management, and an index sensor (not shown) that detects the position of the reel index. .

The setting key type switch 52 is used when changing the setting values of the pachi-slot machine 1 (for example, 6 levels of settings 1 to 6) (setting change), or when checking the settings of the pachi-slot machine 1 (setting confirmation). used for. Here, the setting value indicates the degree of advantage of the player regarding the game, and usually, the lower the setting value (for example, the closer to setting 1), the relative degree of advantage the player has. The higher the setting value (for example, the closer it is to setting 6), the higher the degree of advantage of the player becomes. The setting key-type switch 52 is turned on when, for example, an administrator at the game parlor inserts a setting key (not shown) into the keyhole and turns it counterclockwise from the initial position, and returns it to the initial position from the counterclockwise position. and turns off. Note that when the pachi-slot machine 1 is powered off, turning on the setting key-type switch 52 and then turning on the power will enable settings to be changed, and the settings can be changed while the pachi-slot machine 1 is powered on. When the key-type switch 52 is turned on, settings can be confirmed.

The reset switch 53 is capable of detecting a reset operation by an administrator at the game parlor. The reset operation is an operation for canceling various error states. Further, the reset switch 53 is capable of detecting a setting value determination operation by a manager at the game parlor in a state where settings can be changed. Note that when the reset switch 53 is operated in a state where settings can be changed, the setting value increases by 1 each time it is operated (when setting 6 is reached, the setting returns to setting 1). In this way, the setting value determination operation can be performed. Further, the set value determined in this way is determined when the start lever 7 is operated once thereafter. In other words, the start switch 7S is capable of detecting a setting value confirmation operation by the administrator of the game parlor. In this way, when changing the settings, turn on the setting key type switch 52, operate the reset switch 53 to select the setting value, and operate the start lever 7 to confirm the selected setting value. After that, it is necessary to perform a setting change operation such as turning off the setting key type switch 52. Note that this is an example of a setting change operation, and the configuration may be such that the setting change can be performed by other operations. Furthermore, when changing or confirming settings, the current setting value may be displayed on the above-mentioned credit lamp or payout number lamp, for example.

The role ratio monitor device 54 is composed of, for example, a four-digit seven-segment LED, and is provided inside the main control board case. The winning ratio monitor device 54 sequentially displays various ratio information regarding the game that has been aggregated and calculated by the main CPU 101. These ratio information are used by the game parlor manager when checking whether the pachi-slot machine 1 has been tampered with or not. Note that the role ratio monitor device 54 may be mounted on the main control board 71 or on another board (for example, a ratio display board) connected to the main control board 71. It's okay. Further, as long as it is within the cabinet G, it may be provided at another location. For example, it may be provided on the main control board case. Furthermore, a management switch for starting the display on the role ratio monitor device 54 or switching its contents may be provided in the cabinet G, and when this switch is operated, the above-mentioned various ratio information will be displayed. good. Furthermore, on the premise that such a management switch is used, the information display device 14 may also be used as the role ratio monitor device 54, for example. Immediately after the power is turned on or after a predetermined period of time (for example, about 10 seconds, which serves as a buffer considering the time required to start up the main control circuit 100 and the sub-control circuit 200), the role ratio monitor device 54 In order to confirm that the 4-digit 7-segment LED is functioning properly, use a test pattern such as "8.8." (a pattern in which all segment and decimal LEDs light up). It is desirable to have a configuration in which the light is turned on (or blinks) for a period of time.

In the role ratio monitoring device 54, for example, the type of ratio information is displayed in the upper two digits, and the value (%) indicating the ratio information is displayed in the lower two digits. Here, the various ratio information displayed on the role ratio monitor device 54 includes, for example, cumulative specific section ratio information, continuous character ratio information and character ratio information for the most recent 6000 games, and cumulative continuous character ratio information. There is also information on the ratio of accessories.

Specific section ratio information refers to the stop operation that is advantageous to the player within the game section of the target number of games (for example, 175,000 games for "cumulative"; 6,000 games for "last 6,000 games"; the same applies hereinafter). This is information indicating the ratio of the number of games played (or may simply be the number of games played during an advantageous period) in the game period (for example, AT state) in which the information was reported. In addition, continuous accessory ratio information refers to the number of medals paid out in the game section of the target number of games, when the first-class special bonus (RB) is in operation (the consecutive bonuses related to the first-class special bonus) This is information indicating the ratio of the number of medals paid out to the first class special bonus (RB) in a state where the operating device (BB) is operating (including during the operation of the first class special bonus (RB)). In addition, the accessory ratio information indicates that among the number of medals paid out in the game section of the target number of games, the first type special bonus (RB), the second type special bonus (CB), and the normal bonus (SB) ) is the information indicating the ratio of the number of medals paid out during the operation of the first-class special bonus (RB), and here, when the first-class special bonus (RB) is in operation, the first-class special bonus (RB) is operated by the continuous operation device for the first-class special bonus (RB). This concept includes the state in which the first type special accessory (RB) is in operation while the second type special accessory (CB) is in operation. This concept includes the operation of the second type special accessory (CB) in a state where the accessory continuous operation device (MB) according to the above is in operation.

Note that the game period in which information on stop operations advantageous to the player was being reported (for example, AT state) is considered to be when the accessory is in operation or when the accessory continuous operation device is in operation, and the respective percentage information is It can also be subject to aggregation and calculation. That is, the role ratio monitoring device 54 may be any device that appropriately displays necessary ratio information, and the various ratio information that can be displayed is not limited to these. For example, when displaying continuous accessory ratio information on a model that is not equipped with the first class special accessory (RB), or when displaying specific section ratio information on a model that is not equipped with an advantageous section function (AT function). For models that do not have the corresponding numerical information (correspondence information), when displaying the item, the last two digits of the four-digit 7-segment LED display the numerical information (% information indicating the ratio). On the 7-segment LED, for example, by displaying an identification display for non-compatible information, such as lighting up two vertical bars in the center, such as "--", it is possible to confirm that the model does not have compatible information. It is desirable that the user can recognize the information at a glance.

The door opening/closing monitoring switch 56 is provided, for example, on the opening/closing side (right side) of the lower door mechanism DD. Note that it may be configured to be provided on the back side of the lower door mechanism DD, or may be configured to be provided on the cabinet G side. Further, the upper door mechanism UD may also be configured to be provided with a similar door opening/closing monitoring switch. The door opening/closing monitoring switch 56 is turned on when the lower door mechanism DD is in the open state, and turned off when the lower door mechanism DD is in the closed state, thereby monitoring the opening and closing of the lower door mechanism DD. Note that when the door opening/closing monitoring switch 56 is turned on, a door opening error occurs. In this case, the error state is canceled when the lower door mechanism DD is brought into the closed state.

A ROM cartridge board 202, a main display device 210, and a sub display device 220 are electrically connected to the sub control board 72. Further, the sub control board 72 is connected via the sub relay board 74 to a 24h door monitoring unit 61, a group of performance buttons such as the performance buttons 10a and 10b, lamps/LEDs such as the upper lamp 23, and speakers 35a and 35b. A group of speakers such as the following are electrically connected.

Note that the ROM cartridge board 202, the main display device 210, the sub display device 220, the presentation button group, the lamps/LEDs, and the speaker group have already been described, so their description will be omitted here.

The 24h door monitoring unit 61 is provided, for example, on the opening/closing side (right side) of the lower door mechanism DD, similarly to the door opening/closing monitoring switch 56. Note that it is the same as the door opening/closing monitoring switch 56 in that it has the function of monitoring the opening/closing of the lower door mechanism DD, but by allowing such monitoring to be performed on the sub control circuit 200 side as well, the lower door mechanism DD can be further improved. The opening/closing history of the door mechanism DD can be saved for a certain period of time. Note that this opening/closing history can be confirmed from the hall menu described later. Therefore, for example, if there is a history of the game being opened after the manager of the game parlor has left after business hours, or if there is a history of the game being opened and closed for a long time during business hours, this may result in fraudulent activity. It is now possible to recognize that there is a high possibility that an act has been committed.

[3. Pachislot machine function flow]
Next, the functional flow of the pachi-slot machine 1 will be explained with reference to FIG. Note that FIG. 4 is a diagram for explaining the functional flow of the pachi-slot machine 1.

When a player inserts a medal into the pachislot machine 1 (performs a bet operation) and operates the start lever 7 (performs a start operation), a random number from a predetermined range (for example, 0 to 65535) is selected. One random number (in this embodiment, this may be described as an "internal lottery random number") is extracted.

An internal lottery means (main CPU 101 that performs an internal lottery process to be described later) performs a lottery based on the extracted random number value and determines an internal winning combination. By determining the internal winning combination, combinations of symbols that are permitted to be displayed on the active line are determined in advance. In addition, the types of symbol combinations are those related to "winning" where the player is given benefits such as medal payout, replay activation, bonus activation, etc., and those related to other so-called "losing". The following shall be provided. Furthermore, the winnings related to the payout of medals are called "small winnings", the winnings related to the activation of replays are called "replay winnings", and the winnings related to the activation of bonuses (bonus status) are called "bonus winnings". to be called. Furthermore, a winning combination that can be internally won (that is, a combination of symbols that is permitted to be realized) is sometimes simply referred to as a "winning combination." Further, the internal winning combination is sometimes referred to as a "winning combination," "predetermined result," or "derivation permissible condition." Further, the internal lottery means is sometimes referred to as a "winning combination determining means", "winning combination determining means", "advance determining means", or "derivation permissible condition determining means".

Further, when the start lever 7 is operated (a start operation is performed), the plurality of reels are rotated. Thereafter, when the player operates the stop button (stop button 8L, 8C, 8R) corresponding to the reel (reels 3L, 3C, 3R) (stop operation is performed), the reel stop control means (described below) The main CPU 101) that performs reel stop control processing performs control to stop the rotation of the corresponding reel based on the internal winning combination and the timing at which the stop button is pressed (or the order in which the stop button is pressed). Note that the operating means for performing the starting operation is not limited to a lever-shaped one such as the start lever 7, but any operating means may be used as long as the player can perform the starting operation. good. Further, the operation means for performing the stop operation is not limited to button-shaped ones such as the stop buttons 8L, 8C, and 8R, but any operation that allows the player to perform the stop operation may be used. It may be a means.

In the pachi-slot machine 1, control is basically performed to stop the rotation of the corresponding reel within a specified time (190 msec) from when the stop button is pressed. In this embodiment, the number of symbols that move as the reels rotate within this specified time is referred to as the "number of sliding pieces." In this embodiment, when the prescribed period is 190 msec, the maximum number of sliding pieces (maximum number of sliding pieces) is set to four symbols.

When an internal winning combination that permits the display of winning symbol combinations is determined, the reel stop control means normally causes the symbol combination to appear on the active line within a specified time of 190 msec (4 symbols). Stop the reel rotation so that it is displayed as much as possible at the top. Further, the reel stop control means uses the specified time to stop the rotation of the reels so that symbol combinations whose display is not permitted due to the internal winning combination are not displayed on the active line. Note that the symbols displayed when the reels stop rotating are sometimes referred to as a "stop display" or a "display result." Furthermore, displaying symbols when the rotation of the reels stops is sometimes referred to as "deriving a stop display" or "deriving a display result."

The reel stop control means also includes an automatic reel stop control means that automatically stops each reel when a predetermined automatic stop time has elapsed after the reels have rotated, even if the player has not performed a stop operation. Stop control may also be performed. In this case, the reels will stop without the player's stop operation, so even if any internal winning combination has been determined, any combination of winning symbols will be valid. It is desirable to stop the rotation of the reels so that they are not displayed along the line.

In this way, when the rotation of all the plurality of reels is stopped, the winning determination means (the main CPU 101 that performs winning operation determination processing described later) determines whether the combination of symbols displayed on the active line is related to winning. (or some other predetermined value). That is, it is determined whether or not a winning combination of symbols (or other predetermined symbol combination) has been achieved. The displayed symbol combination is determined by the winning determination means to be a winning symbol (or other predetermined symbol combination) (i.e., a winning symbol combination (or other predetermined symbol combination) ) is established, benefits such as payout of medals are given to the player, or various controls are performed using this as an opportunity. In the pachi-slot machine 1, for example, the above-described series of games is played as one game (unit game).

The winning determination means merely determines whether or not the combination of symbols displayed on the active line corresponds to any one of a plurality of predetermined symbol combinations. Alternatively, it may be determined whether the combination of symbols corresponds to an internal winning combination determined by an internal lottery means. That is, in the former case, it may be determined whether the combination of symbols is related to a winning combination or not, separately from the internal winning combination. In this case, as long as the reel stop control means appropriately performs the stop control, it is possible to sufficiently prevent the occurrence of erroneous winnings, so it is possible to reduce the control burden related to erroneous winning detection. On the other hand, in the latter case, by making it possible to determine whether or not the combination of symbols involved in winning a prize is a combination of symbols that is permitted to win, it is possible to determine whether or not the combination of symbols involved in winning a prize is a combination of symbols that is permitted to win. can be detected, which makes it possible to improve security.

In addition, in pachislot, in the flow of the above-mentioned series of game operations, images are displayed on a display device (for example, the main display device 210, the sub-display device 220, etc.), and light is emitted by various lamps (for example, the upper lamp 23, etc.). Various effects are performed using the output of the sound, the output of sound from the speakers (for example, the speakers 35a, 35b, etc.), or a combination of these. In other words, these are performance execution means that execute the performance. The content of the performance executed by the performance execution means may be determined on the main control circuit 100 side (main side) or may be determined on the sub control circuit 200 side (sub side). In other words, any of these can serve as a performance content determining means.

For example, when the start lever 7 is operated (a start operation is performed), a random number value for performance is extracted separately from the random number value for internal lottery. When the random number value for production is extracted, the production content determining means determines the production to be executed this time from among the multiple types of production content associated with the internal winning combination (or according to predetermined conditions). decide.

Next, when the performance content is determined by the performance content determining means, the performance execution means executes a corresponding performance in conjunction with each opportunity such as when the reels start rotating, when each reel stops rotating, and when determining whether or not there is a prize. Execute. In this way, in the pachislot machine 1, for example, by executing the performance contents associated with the internal winning combination, the internal winning combination (in other words, the combination of symbols to be aimed at, the order of pressing to be performed, etc.) is determined. The player is provided with an opportunity to know or predict what the player can do, which can increase the player's interest.

[4. Basic specifications regarding playability of pachislot machines]
Next, the basic specifications regarding the playability of the pachi-slot machine 1 will be explained.

[4-1. Design arrangement]
As described above, the pachi-slot machine 1 is designed to play a game by displaying a plurality of symbols in a variable and static manner. Therefore, the main control circuit 100 needs to be configured to be able to grasp which symbol is placed at which position on each reel 3L, 3C, 3R. For this reason, the main ROM 102 stores at least data for identifying the type of symbol at each symbol position on each reel 3L, 3C, 3R. Note that, as long as such an objective is achieved, various data configurations can be adopted, but in this embodiment, a symbol arrangement table (see FIG. 9), which will be described later, is used as an example.

In the symbol arrangement table, symbol position data (for example, "0" to "19") indicating each symbol position in the rotational direction of each reel 3L, 3C, 3R is defined. Further, data for specifying the type of symbol (for example, a symbol code) is associated with each symbol position data. Further, in the symbol arrangement table, the position of the symbol located in the middle area of each reel within the frame of the main display window 4 when the reel index is detected is defined as "0". Note that the number of symbols in each row, the number of types of symbols, the maximum number of sliding pieces, etc. can be changed and defined as appropriate.

[4-2. Design combination]
As mentioned above, the pachi-slot machine 1 is designed so that the combination of displayed symbols influences the game result. That is, the pachislot machine 1 grants various benefits, transitions from the current state to a relatively advantageous state, or transitions from the current state to a relatively disadvantageous state, depending on the combination of displayed symbols. This makes it possible to migrate. Therefore, the main control circuit 100 needs to be configured to be able to grasp such symbol combinations. Therefore, data for specifying such combinations of symbols is defined in the main ROM 102. Note that as long as this purpose is achieved, various data configurations can be adopted, but in this embodiment, a symbol combination table (see FIGS. 11 to 14), which will be described later, is used as an example. ing.

In the symbol combination table, data indicating the types of predetermined symbol combinations among the symbol combinations that can be displayed on the active line (for example, "display combination" or "winning activation flag") is defined. ing. Note that the symbols constituting each symbol combination can be specified using, for example, the above-mentioned symbol code. Furthermore, data indicating the type of privilege (for example, "payout, etc.") is associated with each symbol combination. The symbol combination table basically has a data structure corresponding to a winning flag storage area, a winning activation flag storage area, and a symbol code storage area (see FIG. 17), which will be described later. Note that the number of types of symbol combinations, the content of benefits, etc. can be changed and defined as appropriate.

[4-3. Internal winning role]
As described above, the pachi-slot machine 1 is designed so that which symbol combinations are allowed to be displayed (determined in advance) influences the game result. That is, the Pachislot machine 1 determines the internal winning combination (i.e., the type of symbol combinations that can be displayed (or the types of benefits that can be awarded)) prior to (in advance) the player's stop operation. It is possible. Therefore, the main control circuit 100 needs to be configured to be able to grasp such internal winning combinations. Therefore, data for specifying such an internal winning combination is defined in the main ROM 102. Note that various data configurations can be adopted as long as such an objective is achieved, but in this embodiment, an internal lottery table (see FIG. 10), which will be described later, is used as an example.

The internal lottery table includes data indicating the types of a plurality of predetermined internal winning combinations (for example, "No." or "winning number"), and lottery values for determining each internal winning combination in each gaming state. is defined. Note that the lottery value may vary depending on the set value. Further, types of symbol combinations that are permitted to be displayed (corresponding to) are associated with each internal winning combination. In addition, in the pachislot machine 1, it is possible to associate a plurality of symbol combinations with one internal winning combination, and when such an internal winning combination is determined, which symbol combination is displayed? is determined by stop control.

Here, for example, in the later-described internal lottery process of this embodiment (see FIG. 26; more specifically, the internal winning combination determination process of S64), first, a numerical value range predetermined by the random number circuit (for example, 0 65535) are sequentially added and updated with the lottery values defined corresponding to each internal winning combination. Next, it is determined whether the lottery result (lottery value + random number value) exceeds 65535 (whether the lottery result has overflowed or not). Then, in a predetermined internal winning combination, when the result of the determination exceeds 65535, the internal winning combination is made to win (the internal winning combination is determined). However, if no winning combination exceeds 65535 even after making this determination for all internal winning combinations, the internal winning combination in the current game will be a "lose". Note that this is just an example of internal lottery processing, and as long as an appropriate lottery is performed according to the lottery value (winning probability), various methods can be used for the lottery processing. For example, the extracted random numbers are updated by sequential subtraction with the lottery values specified corresponding to each internal winning combination, and then whether or not the subtraction result (lottery result) is less than 0 (the lottery result underflows) is updated. The internal winning combination may be determined by determining the internal winning combination.

In this way, in the internal lottery table, the probability that an internal winning combination with a larger prescribed lottery value is determined (winning probability) becomes higher. Note that the winning probability of each internal winning combination can be expressed by "Lottery value specified for each winning number/Number of all random numbers that may be extracted (random number denominator: 65536)".

[4-4. Stop control]
As mentioned above, in the pachislot machine 1, the game result is determined by which symbol combination is finally displayed by the player's stop operation among the symbol combinations that are permitted to be displayed based on the determination of the internal winning combination. It is a specification that affects the. In other words, the Pachislot machine 1 determines the final display based on not only the determined internal winning combination type but also the player's stop operation timing and press order (also referred to as "stop operation mode" or "stop operation procedure"). It is possible to perform control (stop control) to vary (determine) the type of combination of symbols to be displayed. Therefore, the main control circuit 100 needs to be configured to be able to grasp the manner in which the stop control is to be performed for each internal winning combination according to the manner in which the player performs the stop operation. For this reason, the main ROM 102 defines data for specifying the mode of such stop control. Note that as long as this purpose is achieved, various data configurations can be adopted, but in this embodiment, as an example, a stop table, a pull-in priority table (not shown), etc. are used. There is.

In the stop table, data indicating the movement amount of symbols (for example, "number of sliding pieces") is defined for each symbol position data of each reel 3L, 3C, and 3R. For example, assume that a predetermined stop table is selected in a game in which a predetermined internal winning combination has been determined. Next, it is assumed that a stopping operation is performed on the rotating reel 3L. At this time, it is assumed that the stop start position (symbol position data in the middle region of the reel 3L when the stop operation is performed) is "0". Assume that in the predetermined stop table, the number of sliding pieces specified by the symbol position data "0" is "4". Then, the main control circuit 100 performs control so that the reel 3L is stopped at the symbol position moved by four symbols (the position of the symbol position data "4") (the scheduled stop position becomes "4"). In this way, the stop table defines data (the number of sliding pieces) that makes it possible to directly determine the stop position. Note that such a data structure is also just an example. Furthermore, performing stop control using such a stop table is generally referred to as "table control."

The attraction priority table contains data indicating which symbol combination should be preferentially displayed (drawn) when there are multiple symbol combinations that are permitted to be displayed (for example, "Attraction priority order"). ”) are stipulated. For example, assume that a predetermined attraction priority table is selected in a game in which a predetermined internal winning combination has been determined. Here, the predetermined internal winning combination allows the display of symbol combination A and symbol combination B, and the predetermined attraction priority table is set such that symbol combination B is displayed preferentially than symbol combination A. It is assumed that the order of priority is specified. Next, it is assumed that a stopping operation is performed on the rotating reel 3L. At this time, it is assumed that the stop start position is "0".

Then, the main control circuit 100 determines whether the symbols constituting symbol combination A and the symbols constituting symbol combination B are different for each symbol position within the range of the maximum number of sliding pieces (for example, "4") including the stop start position. Search to see if it exists. If both symbols are not present, the position to stop is determined according to predetermined rules (for example, to stop at a closer position, to stop at a farther position, etc.). If there are only symbols constituting symbol combination A, it is determined to stop at a position corresponding to the symbol. If there are only symbols constituting symbol combination B, it is determined to stop at a position corresponding to the symbol. If both symbols are present, symbol combination B will be displayed preferentially over symbol combination A, so it is decided to stop at a position corresponding to the symbols constituting symbol combination B. In addition, the pull-in priority may be stored for all symbol positions while the target reel is rotating, or when a stop operation is performed on the target reel, according to the selected pull-in priority table. When the symbol is moved, each symbol position within the range of the maximum number of sliding pieces including the stop start position may be stored. Moreover, such a data structure is also just an example. Furthermore, performing stop control using such a pull-in priority table is generally referred to as "control control."

In addition, in this embodiment, it is also possible to adopt a configuration in which the stop control is executed by performing only "table control", or a configuration in which the stop control is executed by performing only "control control". Alternatively, first, perform "table control" to temporarily determine the stopping position, then perform "control control" to search for a more suitable stopping position, and change the stopping position depending on the search results. It is also possible to adopt a configuration that executes stop control that enables this.

In this way, in the pachi-slot machine 1, which symbol combination is finally displayed on the active line is determined based on, for example, the following three factors.

The first element is the determined internal winning combination (the lottery result of the internal lottery process). For example, if the result of the internal lottery process is "lost", the combination of symbols related to any replay role, the combination of symbols related to the minor role, or the combination of symbols related to the bonus role ultimately falls on the active line. It will never be displayed. It should be noted that the "loss" can be considered as one of the internal winning combinations, or it can be taken as a lottery result in which no internal winning combination has been determined.

The second element is the timing of the player's stop operation (the position of the symbol (the pressed position) when the player operates any of the stop buttons). For example, in this embodiment, the maximum number of sliding pieces is set at four symbols, so even if one of the internal winning combinations is won as a result of the internal lottery process, display is permitted. If the symbols constituting the symbol combination are arranged over four symbols on the active line (or on each active line if there are multiple symbols), depending on the timing of the player's stop operation, the combination of the symbols may be may not be displayed. This is called a "missing point."

The third element is the player's press order (the order in which the player operated the stop button). For example, in this embodiment, there are cases where an internal winning combination is determined in which a combination of multiple symbols is associated, and in this case, the combinations of symbols are finally displayed on the active line according to the order in which the symbols are pressed. The combination of symbols may change. In addition, such an internal winning combination is called a ``push order'', and if it is a replay win, it is sometimes called a ``push order replay'', and if it is a small win, it is called a ``push order small win''. It is sometimes called.

[4-5. Game state]
In the pachi-slot machine 1, it is possible to provide various game states as game states in order to vary the degree of advantage for the player or to achieve the intended playability. An example of the gaming state will be explained below.

[4-5-1. Bonus status]
In the pachi-slot machine 1, when a bonus winning combination is won and a combination of symbols related to the bonus winning combination is displayed on an active line, it is possible to shift to a bonus state (activate the bonus state). Note that it is also possible to configure the system so that such a bonus state is not provided. Further, by providing a plurality of types of bonus combinations, it is also possible to configure a plurality of bonus states. When a bonus combination is won, a state (carryover state) occurs in which the bonus combination is carried over as an internal winning combination over a plurality of games until the combination of symbols related to the bonus combination is displayed on the active line. Such a bonus role is sometimes referred to as a "carry-over role." Further, such a carryover state is sometimes referred to as "between (bonus) flags" or "inside (bonus)."

In the bonus state, it is possible to change the lottery mode of the small winning combination (including the probability of winning, its contents, and the mode of stop control, etc.; the same applies hereinafter) compared to the state in which the bonus state is not activated (non-bonus state). (Since it is also a state in which it is possible to change the lottery mode of the replay combination, the bonus state can also be regarded as one mode of the RT state described later). Therefore, when such a lottery mode is a lottery mode that is relatively advantageous to the player, the bonus state becomes a gaming state that is more advantageous than the non-bonus state. On the other hand, if such a lottery mode is a lottery mode that is relatively disadvantageous to the player, the bonus state becomes a gaming state that is more disadvantageous than the non-bonus state.

Examples of bonus roles include the first class special bonus (RB), the bonus continuous activation device (BB) related to the first class special bonus, and the second type special bonus (CB) (but not a carryover role) , an accessory continuous operating device (MB) related to the second type special accessory, and a regular accessory (SB) (however, it is not a carryover winning combination). Further, for example, the bonus status corresponding to each bonus combination is configured as follows. The RB state is a gaming state that ends when a predetermined number of wins (for example, the upper limit is 8) or a predetermined number of games (for example, the upper limit is 12) are played. configured. The BB state is a gaming state that ends when a predetermined number of medals is paid out (for example, the upper limit is 285).

The CB state is configured as a gaming state that ends when one game is played. The MB state is configured as a gaming state that ends when a predetermined number of medals is paid out (for example, the upper limit is 153) or when a player wins an RB or SB during the MB state. Ru. The SB state is configured as a gaming state that ends when one game is played.

Note that the operating condition for the bonus state is not limited to only that the combination of symbols related to the bonus combination is displayed on the active line. For example, when the accessory continuous operating device (BB) related to the first class special accessory is in operation, when the accessory continuous operating device (BB) related to the first class special accessory starts operating, It is also possible to configure the first type special bonus (RB) to be automatically activated at the start of a game when the item is not in operation, or when the first type special bonus is finished being activated. That is, it is also possible to control the RB so that it is always in operation while the BB is in operation, without specifying the combination of symbols related to the RB. Here, the RB in BB operation is sometimes referred to as "JAC" or the like, and a specification in which the RB in BB operation is automatically activated in this way is sometimes referred to as "auto JAC" or the like. Further, while the BB is in operation, control can be performed such that the RB is in operation when a combination of symbols related to the prescribed RB is displayed on the active line. A specification in which the RB operates based on the display of corresponding symbol combinations in this manner is sometimes referred to as "manual JAC" or the like. Further, the relationship between the accessory continuous operating device (MB) related to the second type special accessory and the second type special accessory (CB) is also the same. In other words, without specifying the combination of symbols related to CB, it is possible to control so that the CB is always in operation while the MB is in operation, or it is possible to control the combination of symbols related to the specified CB while the MB is in operation. It is also possible to control so that the CB is activated when the combination is displayed on the valid line.

[4-5-2. RT status]
The pachi-slot machine 1 is capable of transitioning to the RT state (activating the RT state) when predetermined transition conditions are met. Note that it is also possible to configure the system so that such an RT state is not provided. Further, it is also possible to configure a plurality of RT states. The RT state is a state in which it is possible to change the lottery mode of the replay combination compared to a state where the RT state is not activated (non-RT state). Therefore, when such a lottery mode is a lottery mode that is relatively advantageous to the player, the RT state becomes a gaming state that is more advantageous than the non-RT state. On the other hand, if such a lottery mode is a lottery mode that is relatively disadvantageous to the player, the RT state becomes a gaming state that is more disadvantageous than the non-RT state. Further, when providing a plurality of RT states, the same applies to the plurality of RT states. In this case, the RT state in which the lottery mode (especially the probability of winning) of the replay winning combination is relatively advantageous to the player is called a "high RT state" or "high probability replaying state", and the lottery of the replay winning combination is An RT state in which the aspect (particularly the winning probability) is relatively disadvantageous to the player is sometimes referred to as a "low RT state", "low probability replay state", or the like.

For example, the RT state can be transitioned by satisfying any of the following transition conditions. Further, when providing a plurality of RT states, the same applies to the plurality of RT states.
(1) When RB, BB or MB is won (2) When a combination of symbols related to RB, BB or MB is displayed (3) When the RB state, BB state or MB state ends (4) RB, (5) (3) or (4) When a specific symbol combination is displayed when the winning is not in BB or MB (not carried over) and the player is not in RB, BB or MB state. When a predetermined number of games are played after the transition conditions are met.

[4-5-3. AT status]
The pachi-slot machine 1 is capable of transitioning to the AT state (activating the AT state) when predetermined transition conditions are met. Note that it is also possible to configure the system so that such an AT state is not provided. Further, it is also possible to configure a plurality of AT states. For example, the AT state is more advantageous than the state in which the AT state is not activated (non-AT state), because when the player wins the above-mentioned push order combination, information on a stop operation that is advantageous to the player is notified. This is a gaming state configured as a state.

In addition, if multiple AT states are provided, the gaming period of each AT state (including the ease of extension if the said period can be extended (also referred to as "add-on"; the same shall apply hereinafter)), The degree of advantage for the player can be varied by making the types of winning combinations for which stop operation information is reported or the probability of occurrence of stop operation information being reported different. Furthermore, the conditions for transition and termination of the AT state can be set as appropriate depending on the gameplay (excluding termination by execution of limit processing, which will be described later). Further, the AT state may be treated in the same way as the above-mentioned bonus state, and in this case, it may be referred to as a "pseudo-bonus state" or the like.

In addition, the playing period in the AT state may be managed by the number of games (number of games) as long as the period is managed appropriately (game number management), and the predetermined number of games is one set, and the number of sets is (number of sets management). Alternatively, the control may be performed based on the number of payouts or the net increase (difference number) during the AT state (payout number management, difference number management). In addition, it may be managed based on the number of times (navi frequency) that notifications that affect the payout of medals (for example, push order navigation when winning a push order small winning combination) are performed in the AT state (navi number management). The same applies when the AT state is extended. Further, the gaming period given when transitioning to the AT state and the gaming period given when the AT state is extended may be managed by different management methods. Furthermore, when providing a plurality of AT states, they may be managed using the same management method or may be managed using different management methods.

[4-5-4. ART status]
In the pachi-slot machine 1, when predetermined transition conditions are met, it is possible to transition to the ART state (activate the ART state), which is a combination of the above-described high RT state and AT state. In other words, the ART state means an AT state performed in a high RT state, so at least a low RT state and a high RT state are provided as RT states, and a transition to a high RT state (or a transition to a low RT state) is performed. The basic control is the same as the AT state (high RT as a result of being informed of information on stop operations that are advantageous to the player). (or if transition to a low RT state is avoided), it can be said to be synonymous with the AT state). Note that when the transition conditions for the ART state are met, the transition to the AT state may be made first, and then the transition to the high RT state may be performed to transition to the ART state, or the high RT state and the AT state may be simultaneously transitioned ( Alternatively, the state may be shifted to the ART state by shifting to the ART state (substantially simultaneously).

[4-5-5. Other gaming status]
Note that the pachi-slot machine 1 can also provide game states other than the various game states described above. For example, each mode in the advantageous section (see FIGS. 5 and 6), which will be described later, is also a state in which the player plays a game, and the advantage is whether or not to shift to the AT state as a pseudo-bonus state. Since the degree can be varied, these can be considered as gaming states. Further, from a similar viewpoint, for example, a gaming state can be provided in which the degree of advantage of whether or not to shift to a bonus state can be varied. For example, when a bonus winning combination is won (carried over), a gaming state in which the combination of symbols related to the bonus winning combination is likely to be displayed due to stop control, and a combination of symbols related to the bonus winning combination are relatively By providing a gaming state that is less likely to be displayed, the player's degree of advantage can be varied. Furthermore, for example, a game state in which the bonus combination is won with a predetermined probability (easy to win) and a game state in which the bonus combination is won with a probability lower than the predetermined probability (relatively difficult to win) is provided. It is also possible to configure the system so that the degree of advantage for the player can be varied.

In addition, the following methods can be used to change the degree of advantage of whether or not to transition to the AT state (which may also include whether to extend the playing period of the AT state; the same applies hereinafter). You can also. For example, a "specific combination" may be determined as the internal winning combination. The number of medals awarded for the specific combination changes depending on the player's stop operation mode (may be the stop operation timing, the order of the presses, or a combination thereof). (For example, if the stop operation mode is appropriate (correct answer), 8 coins will be paid out; if the stop operation mode is inappropriate (incorrect answer), 1 coin or no coins will be paid out).

Then, if you win the specific combination in a specific gaming state, if 8 coins are paid out, whether or not to change the advantageous degree of whether or not to shift to the AT state in the current game to an advantageous one. No decision is made (which may include a decision as to whether or not to move directly to the AT state, or whether or not to directly extend the playing period in the AT state; hereinafter referred to as an "advantageous decision"). On the other hand, if 8 coins are not paid out, the advantageous determination is made in the current game. Alternatively, if the specific winning combination is won in the above-mentioned specific gaming state, and 8 coins are paid out, the advantageous determination is made in the current game. On the other hand, if eight coins have not been paid out, the advantageous decision will not be made in the current game.

In this way, when a player plays a game using a specific gaming method, there are cases where an advantageous decision is made in the current game as a result of the game, and cases where the advantageous decision is not made (there is a restriction on the occurrence of an advantageous decision). It can also be configured so that there are cases where the Please note that the player may change between the current game and the next game, and if such restrictions continue after the next game, there is a risk that the (next) player will be at a significant disadvantage. Therefore, it is desirable that such restrictions be limited to the current game and not continue from the next game onward. Such restrictions are also sometimes referred to as "penalties."

[4-6. Game section]
In the pachi-slot machine 1, in order to prevent the gambling nature from becoming excessively high, it is possible to provide various game sections as states in which the game is performed with a concept different from the above-mentioned game state. An example of the game section will be explained below. Note that the gaming section is roughly divided into a non-advantageous section and an advantageous section.

(Unfavorable section)
The non-advantageous period is configured as a gaming period in which it is not possible to notify the player of a stop operation mode that is advantageous to the player, and has the following requirements. Note that the requirements below are just examples, and if at least one of the requirements is relaxed or made stricter, it can be changed as appropriate.

(1) It is not possible to inform the player of an advantageous stopping operation mode (for example, push order navigation, etc.). Therefore, control to the above-mentioned AT state or ART state is not possible.
(2) When the set value is changed (setting change) or when an initialization condition such as "RAM abnormality" described later is satisfied, a non-advantageous section is set as the initial state.
(3) When the limit processing described below is executed in an advantageous section (in other words, a predetermined value that is updated as the game progresses during the advantageous section (for example, the number of advantageous section games counter and the number of advantageous section payout counters described below) value) reaches a specified value (for example, 1500 games or 2400 coins), a non-advantageous section is set as the initial state. Note that by referring to the predetermined value, if the predetermined value is a specific updated value even before the predetermined value becomes the specified value, the non-advantageous section may be set based on that. In addition, if a predetermined end condition is met during an advantageous section and the end is determined (for example, if a lottery is configured to end the advantageous section and the winner wins), then A non-advantageous section may be set.
(4) In the non-advantageous section, the processing related to the advantageous section (for example, the process of determining whether to move to the advantageous section, etc.) can only be performed with reference to the determined internal winning combination, and the derived It is not possible to perform processing that refers to various parameters other than the internal winning combination, such as the result display (symbol combination) or the number of games in the non-advantageous section (or the advantageous section before transition). In addition, to determine which internal winning combination has been determined, it is possible to refer to data directly indicating the internal winning combination, such as the winning number, or to check the sub-flag (multiple winning combinations) generated or converted from the data of the internal winning combination. It is also possible to refer to data that indirectly indicates an internal winning combination, such as one data to be determined.
(5) The non-advantageous section is basically one state, and multiple states cannot be set within the non-advantageous section. For example, it is not possible to set the non-advantageous section after the end of the advantageous section as the non-advantageous section A, and the non-advantageous section after the setting change to be the non-advantageous section B, and so on.

(Advantageous section)
The advantageous section is configured as a game period in which it is possible to notify the player of a stop operation mode advantageous to the player, and has the following requirements. Note that the requirements below are just examples, and if at least one of the requirements is relaxed or made stricter, it can be changed as appropriate.

(1) It is possible to notify the player of an advantageous stopping operation mode (for example, push order navigation, etc.). Therefore, it is possible to control to the above-mentioned AT state or ART state.
(2) When the setting value is changed (setting change) or when an initialization condition such as "RAM abnormality" described later is satisfied, an advantageous section cannot be set as the initial state.
(3) When the limit process described below is executed in an advantageous section, it is necessary to terminate the advantageous section.
(4) In the advantageous section, processing related to the advantageous section (for example, processing for determining whether to shift the gaming state (mode) during the advantageous section or whether to extend a specific gaming state (mode), etc.) , it is possible to perform not only processing that refers to the determined internal winning combination, but also processing that refers to various parameters other than the internal winning combination, such as the derived result display (combination of symbols) and the number of games in an advantageous section. . In addition, other examples of various parameters that can be referenced include, for example, benefit information such as points that can be awarded according to the various parameters described above, types of bonus states, types of RT states, and timing of stop operation of any reel. , or the order in which they are pressed.
(5) Multiple states can be set within the advantageous section. For example, it is possible to set a normal state which is disadvantageous for the player, a CZ state where it is easy to shift to the AT state, or an AT state where the expected value of medal increase is positive when the stop operation is performed in accordance with the notification. Further, for example, in response to a decision to transition to the CZ state in the normal state, a CZ precursor may be set as a standby state until the actual transition to the CZ state, and a precursor effect suggesting transition to the CZ state may be performed. In response to a decision to transition to the AT state, or in the normal state or the CZ state, the system may be set as a standby state until the actual transition to the AT state, and a precursor effect suggesting transition to the AT state may be performed. States such as the AT precursor state can also be set according to the gameplay.
(6) It is possible to notify that you are in an advantageous section by lighting the section lamp (status display section) that can notify you whether you are in an unfavorable section or an advantageous section (if the section lamp is off) (It is possible to notify that the vehicle is in a non-advantageous section.) Note that, as described above, the lighting start timing of the section lamp can be set to a certain arbitrary timing. Basically, the lights may start turning on when the transition is from an unfavorable section to an advantageous section, and may continue to be turned on until the transition is made to a non-advantageous section. However, if the advantageous section to which the switch has been transferred is in the normal state, the lighting may not be started, but the lighting may be started when the AT state is first entered. Note that if the transitional advantageous section is in the AT state, lighting may be started from that time.

[4-7. limiter]
In the pachislot machine 1, in order to prevent the gambling aspect from becoming excessively high due to the advantageous section continuing for too long, an upper limit (restriction) is set on the period during which the advantageous section continues continuously. is possible. Such an upper limit is called a "limiter". Furthermore, in the present embodiment, ending the advantageous section using such a limiter is described as execution of limit processing or operation of the limiter. An example of the limiter will be described below.

(Number of games limiter)
The number of games limiter is configured as a limiter that executes a limit process when the number of games (number of games played) in an advantageous period reaches "1500". For example, an advantageous period game counter, which will be described later, starts counting when the advantageous period starts, and increases the count by 1 each time one game is completed. Then, based on the value of the advantageous section game counter reaching a specified value (for example, "1500" or more), the advantageous section is forcibly played (for example, even if the playing period in the AT state remains). It is terminated and moved to a non-advantageous section. Note that the number of games for which the game number limiter operates can be set to any number of games as long as the number of games is less than or equal to the upper limit of "1500". Furthermore, if the requirements for such a game number limiter are to be relaxed or made stricter, they can be changed accordingly. Alternatively, the gambling nature may be suppressed in stages according to the number of games during the advantageous period.

(Payout number limiter)
The payout number limiter is configured as a limiter that executes a limit process when the number of medals paid out during an advantageous section reaches "2400". For example, the advantageous section payout counter described below starts counting from the start of the advantageous section, and each time a medal is paid out, the corresponding number of medals is paid out (more specifically, the net increase is calculated by subtracting the number of bets from the number of medals paid out). (several minutes) Add the count. Then, based on the value of the advantageous section payout number counter reaching a specified value (for example, "2400" or more), the advantageous section is forcibly given (for example, even if the playing period in the AT state remains). It is terminated and moved to a non-advantageous section. Note that the number of payouts at which the payout number limiter operates can be set to any number of payouts that is less than or equal to the upper limit of "2400". Further, if the requirements for such a payout number limiter are to be relaxed or made stricter, they can be changed accordingly. Further, the gambling nature may be suppressed in stages according to the number of medals paid out during the advantageous section.

In addition, for example, the advantageous section payout number counter described below takes the point where the absolute value of the number of medals has decreased the most from the start of the advantageous section as the lowest point (starting point), and counts the positive amount from the latest lowest point. (In other words, if there is no payout, the count is subtracted, etc.). In other words, the payout number limiter executes the limit process when a maximum of "2400" medals are paid out from when the number of medals increases during the advantageous period (for example, when the AT state starts). It can also be configured as a limiter. Further, for example, the advantageous section payout number counter described later may simply count the actual payout number (that is, the number of bets is not subtracted from the payout number) instead of the above-mentioned net increase number.

Note that the pachi-slot machine 1 may execute limit processing for advantageous sections using only the number of games limiter, may execute limit processing for advantageous sections using only the number of payouts limiter, and may execute limit processing for advantageous sections using only the number of games limiter and the number of payouts. The advantageous section limit processing may be executed using both number limiters. Note that when both limiters are used, it is desirable to end the advantageous section when the operating condition for either limiter is satisfied after the start of the advantageous section.

Further, the type of limiter is not limited to the above-mentioned game number limiter and payout number limiter. For example, the number of navigation times for the small winning combination in the push order during the AT state (that is, the number of times information on a stop operation advantageous to the player was notified regarding the winning combination related to the payout of medals) is a predetermined number of times (for example, "400" times). A navigation number limiter may be provided that executes the limit process when the number of times the navigation is reached. That is, as long as the gambling nature can be appropriately suppressed, it is possible to execute the limit process using various conditions related to the game.

[4-8. External signal]
As described above, the pachi-slot machine 1 is designed to be able to output a plurality of types of external signals to the outside. For example, if external signal 1 is turned on based on the start of the bonus state and turned off based on the end of the bonus state, the external data display device will also be able to do this. You can perform effects during the linked bonus state. Further, for example, the external signal 1 is turned on based on the start of the BB state, the external signal 1 is turned off based on the end of the BB state, and the external signal 1 is turned off based on the start of the MB state. If the external signal 2 is turned on based on the completion of the MB state, and the external signal 2 is turned off based on the completion of the MB state, not only the above-mentioned bonus state effect will be performed on the external data display device, but also the bonus state will be displayed. You can count the number of times by type.

Further, for example, if the external signal 1 is turned on based on the start of the AT state and turned off based on the end of the AT state, the external data display device can also In conjunction with this, it is possible to perform effects during the AT state. Further, for example, the external signal 1 is turned on based on the start of a predetermined AT state, the external signal 1 is turned off based on the end of the predetermined AT state, and the specific AT state is turned on. If the external signal 2 is turned on based on the start of a specific AT state, and turned off based on the end of a specific AT state, the external data display will also be able to display the information during the above AT state. In addition to performing performances, it is also possible to count the number of ATs by type.

Also, for example, the AT state is configured as an AT state for managing the number of sets, and the external signal 1 is turned on based on the start of the first set of AT state, and from the second set onwards, the set is started. If the external signal 2 is turned on each time the AT state is hit, the number of initial hits in the AT state and the number of extensions in the AT state can be counted on an external data display. Note that the timing of turning on and turning off each external signal can be set as appropriate. That is, as long as the situation can be appropriately recognized by an external data display, hall computer, etc., the output mode of each external signal can be set as appropriate. For example, various conditions can be adopted for the period from the off state to the on state and then to the off state again, such as a predetermined time, one game, or until the state changes.

[4-9. command]
As described above, the pachi-slot machine 1 is designed to be able to transmit a plurality of types of commands from the main control circuit 100 to the sub-control circuit 200. In addition, in the pachi-slot machine 1, the main control circuit 100 and the sub-control circuit 200 cannot communicate with each other, and it is required that communication be performed only in one direction from the main control circuit 100 to the sub-control circuit 200. ing. Therefore, the main control circuit 100 needs to timely transmit information (commands) for reporting changes in the status of the pachi-slot machine 1 to the sub-control circuit 200. An example of such a command will be explained below.

The main control circuit 100 transmits an initialization command to the sub control circuit 200, for example, when a setting change operation is performed. The initialization command includes parameters that specify setting values, gaming conditions, and the like. Further, for example, when a bet operation is performed, a medal insertion command is transmitted. The medal insertion command is configured to include parameters for specifying the number of bets and the like. Further, for example, when a start operation is performed, a start command is transmitted. The start command is configured to include parameters that specify internal winning combinations, gaming conditions, and the like. Further, for example, when a lock effect is performed, a lock command is transmitted. The lock command is configured to include parameters that specify the contents of the lock performance. Further, for example, when the rotation of each reel 3L, 3C, and 3R starts, a reel rotation start command is transmitted. The reel rotation start command is configured to include a parameter that specifies that rotation of the reels has started.

Further, for example, when a stop operation is performed, a reel stop command is transmitted. The reel stop command includes parameters that specify the reel to be stopped, the position at which the reel is to be stopped, and the like. Further, for example, when all the reels are stopped and the display combination (winning activation flag) is determined, a winning activation command is transmitted. The winning activation command is configured to include parameters that specify the type of display combination, the content of the bonus to be awarded, and the like. Further, for example, when starting an advantageous section, an advantageous section start command is transmitted. The advantageous section start command is configured to include parameters for specifying the start of the advantageous section, the mode (gaming state), and the like. Further, for example, when ending an advantageous section, an advantageous section end command is transmitted. The advantageous section end command is configured to include parameters for specifying the termination of the advantageous section, the cause of the termination, and the like. Further, for example, when a payment operation is performed, a payment command is transmitted. The payment command is configured to include parameters for specifying the number of returns and the like. Note that these are just examples, and commands other than these can be transmitted as needed, and unnecessary commands among these can also be prevented from being transmitted.

[4-10. Performance]
As mentioned above, in the pachi-slot machine 1, various performances are performed using various production devices in order to increase the interest of the game, to provide useful information to the player, or to achieve the intended gameplay. It is now possible. An example of such a performance will be described below.

[4-10-1. Main side performance]
In the pachi-slot machine 1, under the control of the main control circuit 100 (main side), the following effects can be performed, for example. As described above, in the pachi-slot machine 1, it is possible to notify information on a stop operation using the instruction monitor, but this is also included in performance in a broad sense.

(Rock performance)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, an effect can be performed that stops the progress of the game for a predetermined period (disables the player's game operation for a predetermined period). Such a performance is called a "rock performance (or simply "rock")" or a "freeze performance (or simply "freeze")." Note that it is possible to configure the system so that such a rock effect is not performed, or to allow a plurality of types of rock effects to be performed.

Further, the game operation to be invalidated may be, for example, a start operation, a stop operation, or another operation. For example, if the start operation is disabled for a predetermined period, the progress of the game is stopped for a predetermined period after all stop operations have been performed. Further, for example, if the stop operation is disabled for a predetermined period, the progress of the game is stopped for a predetermined period after the start operation is performed. In addition, when providing multiple types of lock effects, the period during which the progress of the game is stopped (period for invalidating the player's game operations), the type of game operations to be invalidated, etc. are set for each lock effect. All you have to do is make it so.

(Reel production)
In the pachi-slot machine 1, when a predetermined execution condition is met, the performance display mode of each reel 3L, 3C, 3R (not only a variable display mode but also a combination with a stop display mode) during the execution of the above-mentioned lock effect. (including). Such a presentation is called a "reel presentation" and also a "symbol presentation." It should be noted that it may be configured so that such reel effects are not performed, or it may be configured such that multiple types of reel effects can be performed. In addition, the phrase "performing (performing) a lock effect" includes both cases where a reel effect is performed and cases where a reel effect is not performed.

In short, reel production is to rotate or stop (temporarily stop) each reel 3L, 3C, 3R without the player's gaming operation during a period when the player's gaming operation is invalidated. It is a performance that will be performed. Therefore, it is possible to set a movement pattern for performing such a performance movement without considering the rotation speed, the maximum number of sliding pieces, etc. Furthermore, by setting a plurality of movement patterns, it is possible to provide a plurality of types of reel effects. Furthermore, by combining multiple types of reel effects and multiple types of lock effects, a wider variety of effect patterns can be set. Note that only one, any two, or all three of the reels 3L, 3C, and 3R may be used for reel production.

(pseudo game)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, an effect that causes a pseudo game to be played during the above-described lock effect can be performed. Such performances are called "pseudo games." It should be noted that the system can be configured so that such pseudo games are not performed, or it can be configured so that multiple types of pseudo games can be performed. In addition, the phrase "performing (executing) a lock effect" includes both cases where a pseudo game is performed and cases where a pseudo game is not performed.

In short, a pseudo game is a process in which a player's game operation is accepted in a pseudo manner during a period in which the player's game operation is invalidated, and thereby the reels 3L, 3C, and 3R are rotated or stopped (temporarily stopped). The performance is performed by doing things like this. That is, the reel performance described above is performed by further intervening the player's game operation. For example, the MAX bet button 6a, 1 bet button 6b, start lever 7, stop buttons 8L, 8C, 8R, and settlement button 9 are basically provided for the purpose of being used for game operations. For this reason, it is inherently undesirable to use it for any other purpose. However, in a simulated game, it is possible to accept these operations on the premise that measures are taken to prevent the player from mistakenly believing that he or she is playing an actual game.

Here, the flow of the pseudo game will be explained using an example. For example, the pseudo game is performed in the following manner.
(1) Actual start operation by the player (here the execution conditions are met and the pseudo game starts)
(2) Each reel rotates in a pseudo manner (during a pseudo game)
(3) Receive a pseudo-stop operation, which causes each reel to temporarily stop (during pseudo-gaming)
(4) After random delay processing, each reel actually starts rotating (the pseudo game ends and the actual game starts)

Note that random delay processing is, for example, when specific symbols are displayed side by side in the situation (3) above, and when each reel starts rotating normally in the situation (4) above, the player In some cases, it becomes easier to stop using a specific symbol as a landmark (helping with so-called "eye pushing"), so in order to correct this, a delay period is randomly assigned to each reel. This is a process for starting rotation after generation (such a delay period is also referred to as a "relocation period"). In addition, when each reel is temporarily stopped in the situations (3) and (4) above, the phase signal in the excitation control of each stepping motor must be set to the specified value so that it is not mistakenly recognized as completely stopped. It is desirable that the reels alternate between forward and reverse directions for less than a period of time (eg, 500 ms).

As one of the above-mentioned measures, for example, if any combination of symbols is temporarily stopped in the situation (3) above (when the third reel is temporarily stopped and all reels are temporarily stopped), In the above-mentioned situation (4), each reel may be slightly vibrated (swinged) up and down until the random delay process is started. In addition, as long as the phase signal changes within the above-mentioned predetermined time, such swinging will not occur when the first reel temporarily stops or when the second reel temporarily stops. You can also do this.

In addition, as one of the above-mentioned measures, for example, a pseudo game lamp is installed to notify that a pseudo game is in progress, and after a pseudo game is started in the situation (1) above, ), the pseudo game lamp may be turned on until the random delay process is started. Note that it is desirable that the pseudo game lamp be installed at a position above the operation section that accepts game operations from the player and at a position where it can be visually recognized during the game. Further, the pseudo game lamp is an independent lamp that is not used for any other purpose, and it is desirable that the entire display portion of the pseudo game lamp is covered with a monochrome edge. Further, it is desirable that the display range of the pseudo game lamp including the explanatory part of the pseudo game lamp has a certain surface area (for example, one side exceeds 10 mm and the surface area exceeds 642 square mm). In addition, the explanatory part of the pseudo game lamp includes a description that allows the user to recognize that the pseudo game lamp is a lamp for notifying that a pseudo game is in progress (for example, "FREEPLAY", "simulating game production in progress", or " It is preferable that the reel should have a description such as ``Reel automatic production in progress'', and it is desirable that such a written part should occupy 1/3 or more of the surface area. It should be noted that it may be the main control circuit 100 or the sub control circuit 200 that controls the pseudo game lamp.

In addition, as one of the above-mentioned measures, for example, a pseudo-gaming display to notify that a pseudo-gaming is in progress may be displayed after the pseudo-gaming is started in the situation (1) above. ) The main display device 210 or the sub display device 220 (or both) may be used until the random delay process is started in the situation described in (). It is preferable that the pseudo-gaming display be displayed above the operation unit that accepts the player's gaming operations and at a position where it can be seen during the game (in this embodiment, the main display device 210 and the sub-display device 220 are located above the operating section, so either one may be used). In addition, the pseudo-gaming display, including the explanation part, must have a certain surface area (for example, one side exceeds 10 mm, and if the display screen is less than 7 inches, the surface area must exceed 642 square mm. , if the display screen is 7 inches or more, the surface area should preferably be 8.2% or more of the entire screen). In addition, the explanatory part of the pseudo-gaming display includes descriptions that make it clear that the pseudo-gaming display is a display to notify that a pseudo-gaming is in progress (for example, "FREEPLAY", "simulating game production in progress", etc.). It is also desirable that the size of the reel is such that it can be read by the player without being obscured.

Also, for example, during a pseudo game (for example, from the start of the pseudo game in the situation (1) above to the start of the random delay process in the situation (4) above), the instruction monitor It is desirable to configure the system so that the information on the stop operation is not notified (if it is necessary to display the information on the stop operation on the instruction monitor in the game, the display is started at the timing when the random delay process is started). In this way, it is possible to further prevent the player from mistakenly believing that he is playing an actual game during a simulated game. Furthermore, if any of the above-mentioned measures are taken, even if the sub-side production device (for example, the main display device 210 or the sub-display device 220) is configured to notify information about the stop operation during the pseudo game. good. Similarly, during the simulated game, the sub-side performance device may perform a performance according to the game result of the simulated game (in conjunction with the simulated game operation).

In addition, in the actual game, a test signal corresponding to the player's game operation or the state in which the game operation is possible is output via the first interface board 301 for the test machine, but during the pseudo game In this case, the test signal corresponding to the player's pseudo game operation or the state in which the pseudo game operation is possible is not output. Therefore, during the pseudo game, a test signal (pseudo game signal) may be outputted so that the test machine can recognize that the pseudo game is being played. Note that when the first interface board 301 for the test machine receives a pseudo game signal from the main control board 71, it outputs a signal for pseudo game progress control to the main control board 71, so that the main control board 71 side performs the pseudo game signal. The game may be progressed (that is, the first interface board 301 for the test machine may be provided with a pseudo game progress function). Further, when the first interface board 301 for the test machine is provided with such a pseudo game progression function, a changeover switch that can turn the function on and off may be provided. As a result, it is possible to arbitrarily set whether or not to confirm the production content of the pseudo game in the certification test (sight shooting test) of the pachi-slot machine 1.

[4-10-2. Sub-side production]
In the pachi-slot machine 1, the following effects can be performed, for example, under the control of the sub-control circuit 200 (sub-side). Note that, as described above, the pachi-slot machine 1 allows the main display device 210 and the like to notify information about a stop operation, but this is also included in performance in a broad sense.

(Normal performance)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, an effect can be performed that is completed in the current game (that is, completed in one game). Such a performance is called a "normal performance" or a "single performance". It should be noted that it may be configured so that such normal effects are not performed, or it may be configured such that multiple types of normal effects can be performed.

(Continuous performance)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, an effect that continues over a plurality of games (that is, continues for a plurality of games) can be performed. Such a performance is called a "continuous reading performance" or a "continuous performance". Note that it is possible to configure the system so that such a continuous performance is not performed, or to perform a plurality of types of continuous performance.

(Operation linked production)
In the pachi-slot machine 1, when a predetermined execution condition is satisfied, a performance can be performed in which the content of the performance can be changed according to a performance operation by a player. Such a performance is called an "operation-linked performance" and is also called a "button performance" or the like. It should be noted that the configuration may be such that such operation-linked effects are not performed, or it may be configured such that multiple types of operation-linked effects can be performed. Further, the operation-linked performance can be configured as a normal performance or as a continuous performance. Furthermore, the performance operations can include not only operations on the performance button group, but also various game operations.

Note that the various effects described above can be used for various purposes. For example, it can be used to suggest or inform setting values, internal winning combinations, game status, game sections, bonus award details, period until the award is awarded, and the like. Further, it can be used to suggest or notify the degree of advantage. Furthermore, these uses are just examples.

(Other performances)
The pachi-slot machine 1 can also perform performances other than the various performances described above. For example, various types of notifications to players or game parlors (for example, notifications to prevent addiction, notifications to prevent forgotten items, error status notifications, demo status notifications, etc.) that are used for purposes other than those mentioned above are also included in production in a broad sense. . Note that the addictive prevention notification may be such that, for example, when an advantageous section ends, a warning or the like indicating this fact is notified. In addition, the forgotten item prevention notification may be such that, for example, when an advantageous section ends or when a payment operation is performed, a warning or the like indicating this fact is notified. Further, the error state notification may be such that a warning or the like indicating the error is notified from the time the error occurs until the error is resolved. In addition, the demo status notification may be such that when a predetermined period of time has elapsed during which no games have been played or when a payment operation has been performed, it is possible to notify that the machine is empty.

[5. First gaming machine]
Next, with reference to FIGS. 5 to 22, a specific example of specifications regarding the gaming performance of the pachi-slot machine 1 will be described as a "first gaming machine." It should be noted that some or all of the various specifications and functions described as the first gaming machine in this embodiment can be applied to other gaming machines described in this embodiment, and Some or all of the various specifications and functions described as another gaming machine in this embodiment can be applied to the first gaming machine in this embodiment. That is, the invention according to this embodiment can be a combination of these as appropriate.

First, in the first gaming machine, the active line is defined as only one line, the above-mentioned "center line." Further, in the first gaming machine, a non-bonus state and a bonus state are provided as gaming states. In addition, the non-bonus state is between the 2BB flag where "F_2BB" (a bonus combination that can only be won in a 2-card bet state, hereinafter simply referred to as "2BB") described later is carried over, and the period between the 2BB flags described below. Between the 3BB flags where "F_3BB" (a bonus role that can only be won in a 3-card bet state.Hereinafter may be simply referred to as "3BB") is carried over, and when no bonus role has been won (carryover). (not flagged) and non-flags. Further, the bonus state includes a 2BB state that transitions in response to the display of a combination of symbols related to 2BB, and a 3BB state that transitions to in response to the display of a combination of symbols related to 3BB. Ru.

Furthermore, in the first gaming machine, it is possible to play a game with two medals bet (2-bet state) and with three medals bet (3-bet state). There is. Note that "bet" means that the player inserts two or three medals into the medal slot 5 in order to play a game, and that the player operates the MAX bet button 6a or 1 bet button 6b. This includes both the placing of two or three medals from the credits, and the automatic placing of two or three medals as a result of winning a replay combination.

[5-1. Game performance of first gaming machine]
Next, the flow of the game in the first gaming machine will be explained with reference to FIGS. 5 to 8. In addition, FIG. 5 is a diagram showing an example of the transition flow of the gaming state in the non-advantageous section and the advantageous section in the first gaming machine, and FIG. 6 is a diagram for explaining an example of each mode in the first gaming machine. FIG. 7 and FIG. 8 are diagrams showing examples of various tables in the first gaming machine.

As shown in FIG. 5, in the first gaming machine, the state in which the player plays the game is roughly divided into a non-advantageous section and an advantageous section, and the advantageous section further includes a performance section (advantageous section/normal game) and an advantageous section. An increased section (advantageous section/pseudo bonus) will be provided. The non-advantageous section is a gaming state (non-AT state) in which information on a stop operation that is advantageous to the player is not reported, and is a gaming state that is disadvantageous to the player. The production section is a gaming state (non-AT state) in which information on stop operations that are advantageous to the player is not reported, and is similar to the non-advantageous section in that it is a gaming state that is disadvantageous to the player, but as will be described later. , differs from the non-advantageous section in that mode transition occurs.

In other words, the non-advantageous section is set as an initial state that is controlled when a game in the advantageous section ends, when a setting change operation is performed, when other initialization conditions are met, or when the factory shipment is made. The production section is a control state as a normal state in which the expectation level of increasing section transition (granting) can be changed by mode transition etc., and the player plays a normal game.

On the other hand, the increase period is a gaming state (AT state) in which information on a stop operation that is advantageous to the player is notified, and is a gaming state that is advantageous to the player. That is, the increase section is a control state as an advantageous state in which the player can increase the number of medals. Note that both the effect section and the increase section are advantageous sections, and by mutually transitioning these sections, they are configured as a series of advantageous sections.

In addition, in the first gaming machine, as shown in FIG. 7(a), in the non-advantageous section, the non-advantageous section sub-flag is set as secondary information (sub-flag) according to the internal winning combination (see FIG. 10 described later). is determined. Note that the sub-flag indicates an internal winning combination that plays a similar role (whether or not it is a lottery target combination, its winning probability, etc.) in various types of lottery related to gameplay (various processes related to advantageous sections) performed by the main control circuit 100. This is information that allows groups to be identified by grouping and assigning the same information. This eliminates the need to provide various data tables for each internal winning combination, so the amount of data can be compressed and the capacity of the main ROM 102 can be avoided. In the non-advantageous section, a lottery is performed using the non-advantageous section sub-flag.

The non-advantageous section sub-flag "Repbell" has internal winning combinations of "F_Replay A" (No. "3"), "F_Replay B" (No. "4"), and "F_Bell123A1" to "F_Bell321B2". ” (No. “10” to No. “33”). The non-advantageous section sub-flag "Weak Che" is determined when the internal winning combination is "F_Cherry" (No. "5"). The non-advantageous section sub-flag "Watermelon" is determined when the internal winning combination is "F_Watermelon" (No. "9"). The non-advantageous section sub-flag "confirmed combination" is determined when the internal winning combination is either "F_confirmed cherry" (No. "6") or "F_reach" (No. "8"). The non-advantageous section sub-flag "Naka Che" is determined when the internal winning combination is "F_Middle Cherry" (No. "7"). It should be noted that, in the non-advantageous section as well, the winning sub-flag and the winning sub-flag may be determined in the same way as in the advantageous section. Furthermore, these correspondence relationships are not limited to those described above.

In addition, in the first gaming machine, as shown in FIG. 7(a), an advantageous section winning time sub-flag is used as secondary information (sub-flag) according to an internal winning combination (see FIG. 10 described later) in an advantageous section. is determined. Further, in the advantageous section, an advantageous section winning time sub-flag is determined as secondary information (sub-flag) according to the combination of displayed symbols. In the advantageous section, a lottery is performed using these advantageous section winning time sub-flags and advantageous section winning time sub-flags.

The advantageous section winning sub-flag "Bell" is determined when the internal winning combination is one of "F_Bell 123A1" to "F_Bell 321B2" (No. "10" to No. "33"). The advantageous section winning sub-flag "Weak Che" is determined when the internal winning combination is "F_Cherry" (No. "5"). The advantageous section winning sub-flag "Watermelon" is determined when the internal winning combination is "F_Watermelon" (No. "9"). The advantageous section winning sub-flag "confirmed combination" is determined when the internal winning combination is either "F_Confirmed Cherry" (No. "6") or "F_Reach" (No. "8"). . The advantageous section winning sub-flag "Naka Che" is determined when the internal winning combination is "F_Middle Cherry" (No. "7").

The sub-flag ``Rip 1'' at the time of advantageous section winning is set to ``Right This is determined when the combination of symbols of ``Up Rip'' is displayed (that is, when the winning combination is ``Rip Up Right''). The sub-flag "Tori Rip 2" when winning an advantageous section is "Parallel" when the internal winning combination is either "F_Replay A" (No. "3") or "F_Replay B" (No. "4"). This is determined when the symbol combination of "Rip" is displayed (that is, when the winning combination is "Parallel Rip").

Here, in the first gaming machine, as will be described later, when the internal winning combination is "F_Replay A" (No. "3"), the combination of "Rip to the right" symbols is not possible between the 3BB flags. A combination of "parallel rep" symbols is displayed between 2BB flags and between non-flags.

In other words, when the internal winning combination is "F_Replay A" (No. "3"), "Toru Reply 1" is determined as the sub-flag when winning an advantageous section between 3BB flags, and between 2BB flags and between non-flags. When winning a prize in a section, "Toru Rep 2" is determined as a sub-flag. In the first gaming machine, when the advantageous section winning time sub-flags are different in this way, various lotteries described later (for example, pseudo-bonus transfer lottery using the pseudo-bonus transfer lottery table shown in FIG. 7(c), The degree of advantage in the mode transition lottery using the mode transition lottery table shown in 8(f) is varied.

In addition, in the first gaming machine, for example, "F_Replay A" (No. "3") is played as a winning combination in which the sub-flag changes depending on whether it is between 3BB flags or between 2BB flags. ) is described as an example, but the manner in which the sub-flag changes when winning an advantageous section is not limited to this. For example, as will be described later, when the internal winning combination is "F_Bell123B1" (No. "12"), the stop control will be different depending on whether it is between 3BB flags or between 2BB flags. Therefore, when winning such a winning combination, the number of medals paid out does not change (or may be changed), and the combinations of symbols displayed are different. A sub-flag may be determined. Then, the degree of advantage in various lotteries described later may be varied in accordance with the difference in the advantageous section winning time sub-flag.

For example, as described later, when the internal winning combination is "F_Watermelon" (No. "9"), regardless of which flag (non-flag) it is between, the pressed position (stop operation timing) ) is appropriate, the combination of "Watermelon" symbols will be displayed, and if the pressed position is not appropriate, the combination of "Watermelon Spills" will be displayed as the result will be missed. When winning a prize, different advantageous section winning time sub-flags may be determined depending on whether the prize can be won without any loss or loss. Then, depending on the difference in the advantageous section winning time sub-flag, the degree of advantage in various lotteries described later may be varied.

For example, when the internal winning combination is "F_Replay A" (No. "3"), the stop operation is performed in a specific manner (for example, the stop operation is predefined) between the 3BB flags. If it is performed in any of the following manners: the pressing order (the correct pressing order), the appropriate pressing position (timing of the stop operation), or a combination of these, the The symbol combination of "Parallel Rip" will be displayed, and if it is not performed in a specific manner, the symbol combination of "Rip to the right" will be displayed, and this will determine the sub-flag when winning a different advantageous section. You can do it like this. Then, depending on the difference in the advantageous section winning time sub-flag, the degree of advantage in various lotteries described later may be varied.

That is, in the first gaming machine, the final stop display mode may differ depending on the number of bets, the gaming state, the mode of the stop operation, or any combination of these regarding the specific combination, All modes that allow different secondary information to be determined depending on different stop display modes, thereby making it possible to vary the degree of advantage, can be applied.

Returning to the explanation of the gameplay of the first gaming machine. In the non-advantageous section, a lottery to move to the advantageous section is performed for each game. Specifically, the advantageous section transition lottery table shown in FIG. At a predetermined timing, a destination mode etc. is determined according to the non-gaming section sub-flag. In addition, when making this determination, there are cases where only the type of mode when moving to an advantageous section is determined ("advantageous section start" in Figure 5), and cases where not only the type of mode but also a shift to a pseudo bonus is determined. There is a case where it is determined (in FIG. 5, "advantageous section start + pseudo bonus start"). However, it is also possible to adopt a specification in which a transition to a pseudo bonus is not determined in a non-advantageous period.

Here, each mode in the first gaming machine will be explained with reference to FIG. 6. In the first gaming machine, the mode is control information (which may also be referred to as a gaming state or a control state) for varying the expectation level of transition (granting) to an increased section (pseudo bonus) in a presentation section (normal game). Yes, in the performance section (normal game), it is determined whether or not to transfer to a pseudo bonus according to this mode, it is decided to maintain an advantageous section, or it is decided to end an advantageous section and move to a non-advantageous section. It is supposed to be done.

Start mode is a relatively unfavorable mode that is easy to stay in when transitioning from a non-advantageous section to an advantageous section (production section), and the expectation level of transitioning to a pseudo bonus is relatively low (see the figure below). 7 (c)), and the expectation level of shifting to a more advantageous mode is also relatively low (see FIG. 8 (f) described later). Although not shown, in the start mode, the ceiling number of games is set to "965 games." The ceiling number of games is used to force the transition to the pseudo bonus when the period of not transitioning to the pseudo bonus reaches a certain period. Therefore, the fewer the number of ceiling games, the more advantageous it is to the player, and the greater the number of ceiling games, the disadvantageous to the player.

Normally, A mode is the easiest mode for players to stay in when playing games, and is a relatively disadvantageous mode, and the expectation level of shifting to a pseudo bonus is relatively low (see (c in Figure 7 below)). ), and the degree of expectation of shifting to a more advantageous mode is also relatively low (see (f) in FIG. 8, which will be described later). Note that in the normal A mode, the ceiling number of games is set to "965 games." In addition, in FIG. 6, "approximately 999G after the pseudo bonus" means that after the pseudo bonus ends, the mode shifts to end A mode or end B mode, which will be described later, and in that mode, 32 games are played without shifting to the pseudo bonus. If a game is played and the normal A mode is selected when transitioning from the non-advantageous period to the advantageous period after the game has been played and the period has shifted to the non-advantageous period, the apparent number of ceiling games is "965 games" + End A The game period in mode or end B mode is "32 games" + the number of games required to transition from the non-advantageous section to the advantageous section, so this is expressed. The same applies to the normal B mode, heaven preparation mode, and chance mode.

Normal B mode is relatively easy for players to stay in while playing games, and although it is a relatively disadvantageous mode, it is more advantageous than normal A mode, and the expectation level for shifting to pseudo bonuses is This is relatively low (see (c) in FIG. 7, which will be described later), and the degree of expectation for shifting to a more advantageous mode is also relatively low (see (f), in FIG. 8, which will be described later). Note that in the normal B mode, the ceiling number of games is set to "965 games."

In the Heaven Preparation Mode, the expectation level of transitioning to a pseudo bonus is relatively low (see (c) in Figure 7 below), but the ceiling number of games is set to "466 games", and when transitioning to a pseudo bonus After that, it is certain that the mode will shift to the heaven mode (see (f) in FIG. 8, which will be described later), so in that sense, it is a relatively advantageous mode.

Chance mode has a relatively high expectation of transitioning to a pseudo-bonus (see (c) in Figure 7 below), and the ceiling number of games is set to 222 games, so it is relatively advantageous in that sense. mode. However, the level of expectation for transition to heaven mode is not high (see (f) in FIG. 8, which will be described later).

End A mode is a relatively disadvantageous mode that is easy to stay in if you transition to a pseudo-bonus and do not transition to heaven mode (including heaven preparation mode) after it ends, and there is no expectation of transitioning to a pseudo-bonus. The degree of expectation for shifting to a more advantageous mode is also relatively low (see (f) of FIG. 8, which will be described later). In the termination A mode, if 32 games are played without transitioning to the pseudo bonus after the pseudo bonus ends, the advantageous section itself ends and the game shifts to the non-advantageous section.

End B mode is a relatively disadvantageous mode, but it is more advantageous than end A mode, as it is easy to stay in if you transition to a pseudo-bonus and do not transition to heaven mode (including heaven preparation mode) after it ends. mode, the expectation level to shift to a pseudo-bonus mode is relatively low (see Figure 7 (c) below), and the expectation level to shift to a more advantageous mode is also relatively low (see Figure 7 below). (See 8(f)). In the end B mode, as in the end A mode, if 32 games are played without transitioning to the pseudo bonus after the end of the pseudo bonus, the advantageous section itself ends and the game shifts to the non-advantageous section. Note that the end A mode and the end B mode can also be collectively referred to as "end mode."

The guarantee mode is a mode to stay in when the heaven C mode ends, and the expectation level for transitioning to the pseudo bonus is relatively high (see (c) in Figure 7 below), and the ceiling number of games is "32 games". In that sense, it is a relatively advantageous mode. However, the level of expectation for transition to heaven mode is not high (see (f) in FIG. 8, which will be described later). That is, when Heaven C mode ends, it is positioned as a mode that maintains (guarantees) a relatively advantageous state for a certain period of time in order to prevent a decline in interest due to it.

Heaven A mode may include the extension (addition) of pseudo bonuses in a row (if the AT state continues due to a decision to extend (addition) made during the AT state). The same applies hereafter), the expectation level for transitioning to a pseudo bonus is relatively high (see (c) in Figure 7 below), the ceiling number of games is set to "32 games", and the ceiling It is a relatively advantageous mode with a moderate probability that the mode will be maintained (heaven mode loop rate). Although not shown in FIG. 6, for example, the ceiling mode loop rate may be set differently. For example, when the set value is an odd number (1, 3, 5), the ceiling mode loop rate is about 75%, and when the set value is an even number (2, 4, 6), the ceiling mode loop rate is about 67%. The lottery value can be set so that , or the lottery value can be simply set so that the higher the set value is, the higher the ceiling mode loop rate is. The same applies to heaven B mode and heaven C mode, which will be described later, and a setting difference can be provided in the ceiling mode loop rate.

Heaven B mode is a mode in which you can expect pseudo-bonuses to be played consecutively, and the expectation of transitioning to pseudo-bonuses is relatively high (see (c) in Figure 7 below), and the ceiling number of games is 32 games. ”, and is a relatively advantageous mode with a high probability that the ceiling mode will be maintained (heaven mode loop rate). In other words, this mode is more advantageous than the heaven A mode in terms of the ceiling mode loop rate.

Heaven C mode is a mode in which you can expect pseudo-bonuses to be played consecutively, and the expectation level for transitioning to pseudo-bonuses is relatively high (see (c) in Figure 7 below), and the ceiling number of games is 32 games. '', and the probability that the ceiling mode will be maintained (heaven mode loop rate) is set to be quite high, making it a relatively advantageous mode. That is, in terms of the ceiling mode loop rate, this mode is more advantageous than the heaven A mode and the heaven B mode. Note that heaven A mode, heaven B mode, and heaven C mode can be collectively referred to as "heaven mode."

Note that each of the above-mentioned modes is just an example, and the configuration of the mode is not limited to this. Modes other than the above-mentioned modes may be set, or some of the above-mentioned modes may not be set.

Furthermore, although the non-advantageous section has been described as being relatively less advantageous than the advantageous section, the relationship between the non-advantageous section and the advantageous section is not limited to this. For example, in the case of a non-advantageous section, the transition rate to the increased section is higher than when at least one mode is set in the advantageous section, or the average number of games required to shift to the increased section is shorter. It is also possible to make a specification such that the non-advantageous section is the most likely to be an increasing section. By doing this, an incentive is created to play games even in a state where it is determined that the area is not advantageous, such as after a setting change, and therefore, there is an incentive to start playing games even when the store opens. In addition, even if the section lamp stops lighting after 32 games have passed after the end of the pseudo bonus, it is not determined that the most disadvantageous situation will occur, so even in such a case, there is no incentive to continue playing. becomes. In addition, up to this point, we have explained that the production section is a gaming state in which information on stop operations that are advantageous to the player is not notified, but compared to the increase section, there are disadvantageous aspects (for example, reducing the frequency of notifications, (such as changing the winning combination), it is also possible to set the game state in which information on a stop operation is notified.

Returning to the explanation of the gameplay of the first gaming machine. In the performance section (normal game), first, for each game, a pseudo bonus transition lottery (when winning) is performed with reference to the advantageous section winning time sub-flag. Specifically, during the game after the pseudo-bonus transition lottery table shown in (c) of FIG. At a predetermined timing, it is determined whether or not to shift to a pseudo bonus according to the advantageous section winning sub-flag. In addition, in (c) of FIG. 7, "non-winning" means not to transfer to a pseudo bonus, "winning (current game)" means to transfer from the current game to a pseudo bonus, and " "Winning (next game)" means transitioning to a pseudo bonus from the next game.

In addition, in the first gaming machine, if a "win (current game)" is determined, the game will be played at the start of the current game, and if a "win (next game)" is determined, the game will be played at the start of the next game. After the operation (stop operation) is disabled for a certain period of time, and during the invalid period, a reel performance ("Red 7 set" performance) in which "Red 7" symbols are displayed in a row on the main display window 4 is performed. , in a game where a pseudo bonus has started and a "red 7" effect is performed, if it is necessary to notify information on a stop operation, at least the invalid period has ended and the game operation (stop operation) is valid. The information on the stop operation is notified when (it may be before, but not before the above-described random delay process is started).

In the production section (normal game), if it is determined to shift to a pseudo bonus as a result of the pseudo bonus transition lottery (at the time of winning), a mode transition lottery (at the time of winning) is performed. Specifically, the mode transition lottery table shown in FIG. 8(f) is referred to, and the destination mode is determined according to the current mode and the advantageous section winning sub-flag. Note that this destination mode may be a mode including during the pseudo bonus, or may be a mode after the pseudo bonus ends. In addition, as a result of the pseudo bonus transfer lottery (at the time of winning), if it is decided to transfer to a pseudo bonus and the mode transfer lottery (at the time of winning) is performed, the pseudo bonus transfer lottery (at the time of winning) and mode transfer lottery described below. (at the time of winning) and mode transition lottery (at the time of ceiling) are not performed.

In the production section (normal game), if it is not determined to transfer to a pseudo bonus as a result of the pseudo bonus transfer lottery (at the time of winning), for each game (more specifically, "F_Replay A" or "F_Replay" B), a pseudo bonus transfer lottery (at the time of winning) is performed with reference to the advantageous section winning time sub-flag. Specifically, the pseudo-bonus transition lottery table shown in FIG. At a predetermined timing (before the start of the game), it is determined whether or not to shift to a pseudo bonus depending on the advantageous section winning time sub-flag.

In addition, in the pseudo-bonus transition lottery table shown in FIG. 7(c), "Toripu 2" is determined as the advantageous section winning sub-flag rather than "Toripu 1" is determined as the advantageous section winning sub-flag. The percentage of cases where it is decided to shift to pseudo bonuses is higher. However, the manner in which "Toru Reply 2" is given preferential treatment than "Toru Reply 1" is not limited to this. For example, in the case where "Toripu 2" is determined as the sub-flag when winning an advantageous section, it may be decided to transfer to a pseudo bonus with a predetermined probability; In such a case, it may not be possible to decide to shift to a pseudo bonus.

In the performance section (normal game), if it is determined to shift to a pseudo bonus as a result of the pseudo bonus transition lottery (at the time of winning), the mode transition lottery (at the time of winning) is performed. Specifically, the mode transition lottery table shown in FIG. 8(f) is referred to, and the destination mode is determined according to the current mode and the advantageous section winning time sub-flag. Note that this destination mode may be a mode including during the pseudo bonus, or may be a mode after the pseudo bonus ends. Further, as a result of the pseudo bonus transfer lottery (at the time of winning), it is determined to transfer to the pseudo bonus, and if the mode transfer lottery (at the time of winning) is performed, the mode transfer lottery (at the time of ceiling), which will be described later, will not be performed.

In addition, in the mode transition lottery table shown in FIG. 8(f), "Toripu 2" is determined as the advantageous section winning sub-flag rather than "Toripu 1" is determined as the advantageous section winning sub-flag. In this case, the percentage of decisions to shift to a mode relatively advantageous to the player is higher. However, the manner in which "Toru Reply 2" is given preferential treatment than "Toru Reply 1" is not limited to this. For example, in the case where ``Pass 2'' is determined as the advantageous section winning sub-flag, it may be determined to shift to a mode that is relatively advantageous to the player with a predetermined probability, but the advantageous section winning sub-flag may be `` In the case where it is determined that the game mode is 1, it may not be determined to shift to a mode that is relatively advantageous to the player.

In the performance section (normal game), if it is not determined to transfer to a pseudo bonus as a result of the pseudo bonus transfer lottery (at the time of winning), the number of ceiling games is updated (either addition method or subtraction method is fine), and the ceiling game When the number reaches the ceiling number of games associated with the current mode (or predetermined at the time of transition to an advantageous section, etc.), it is determined to shift to a pseudo bonus. In this case, it is possible to make sure that a "win (current game)" is determined, or it is also possible to make sure that a "win (next game)" is determined. Further, any of these may be determined by lottery.

In the performance section (normal game), when the number of games reaches the ceiling and it is decided to shift to a pseudo bonus, a mode transition lottery (at the time of ceiling) is performed. Specifically, the mode transition lottery table shown in FIG. 8(f) is referred to, and the destination mode is determined according to the current mode. Note that this destination mode may be a mode including during the pseudo bonus, or may be a mode after the pseudo bonus ends.

The processes related to the pseudo-bonus transfer lottery (at the time of winning) and the pseudo-bonus transfer lottery (at the time of winning) differ only in the type of sub-flag, and the rest of the processing content is the same, so they use the same lottery table and control flow. It can be controlled using In addition, the processes related to the mode transition lottery (at the time of winning) and the mode transition lottery (at the time of winning) are the same except for the type of sub-flag, so they use the same lottery table and control flow. can be controlled.

In addition, if "Winning (this game)" is not set as the type of winning of the pseudo bonus, at the timing when the advantageous section winning sub-flag is determined, the advantageous section winning sub-flag has already been determined, and, Since the number of ceiling games can also be updated, the pseudo bonus transfer lottery (at the time of winning), the pseudo bonus transfer lottery (at the time of winning), and the pseudo bonus transfer processing when the ceiling is reached can be performed all at once. can. Similarly, the mode transition lottery (at the time of winning), the mode transition lottery (at the time of winning), and the mode transition lottery (at the time of ceiling) can be performed all at once in one process.

Returning to the explanation of the gameplay of the first gaming machine. As mentioned above, when it is decided to shift to a pseudo bonus in the performance section (normal game) and the pseudo bonus is started ("pseudo bonus start" in Figure 5), the transition to the increase section (pseudo bonus) occurs. . In addition, as mentioned above, in the performance section (normal game), if the end A mode or end B mode is controlled and 32 games are played without transitioning to the pseudo bonus (in Figure 5, the "Advantage section ends" (via Ends A and B)"), then shift to a non-advantageous section. Furthermore, if the conditions for limit processing shown in FIG. 16, which will be described later, are satisfied, the advantageous section will be forcibly terminated ("end of advantageous section (limit processing)" in FIG. 5), and as a result, Shift to a non-advantageous section.

In the increase section (pseudo-bonus), a ceiling reduction lottery is performed when the pseudo-bonus starts. Specifically, the ceiling reduction lottery table shown in FIG. 8(e) is referred to, and it is determined whether or not to shorten the number of ceiling games after the end of the pseudo bonus, depending on the current mode. In (e) of Figure 8, "non-winning" means that the number of ceiling games will not be shortened, and "winning (number of ceiling games = 0 update)" means that after the pseudo bonus ends, regardless of the mode. , means that the number of ceiling games to be set is set to "0" (reduced). Note that the ceiling reduction lottery may be performed not only when the pseudo bonus is started, but also every game during the pseudo bonus.

As a result of the ceiling reduction lottery, if it is decided not to reduce the number of ceiling games, when the pseudo bonus ends, if you do not have 1G continuous stock described below, the number of ceiling games will be reduced according to the current mode. is set (in the case of end mode, it is not set because the advantageous section ends after 32 games (and is cleared accordingly), but the ceiling number of games may be temporarily set here) , the pseudo bonus ends ("pseudo bonus ends" in FIG. 5), and the game moves to the performance section (normal game). On the other hand, if it is determined to shorten the number of ceiling games as a result of the ceiling reduction lottery, when the pseudo bonus ends, "0 games" is set as the ceiling number of games. As a result, the pseudo bonus will be started again from the next game after the pseudo bonus ends. In this case, since the pseudo bonus is started when the number of games reaches the ceiling, the above-described mode transition lottery (at the time of ceiling) is performed.

In the increased section (pseudo-bonus), a mode transition lottery (at the time of winning) is performed for each game (more specifically, in a game in which "determined hand" or "medium Che" is determined as the sub-flag when winning the advantageous section). . Specifically, the mode transition lottery table shown in FIG. 8(f) is referred to, and the destination mode is determined according to the current mode and the advantageous section winning sub-flag. Note that the destination mode may also be determined when an advantageous section winning sub-flag other than the above is determined, but in this case, as a general rule, a mode that is relatively disadvantageous than the current mode is selected. In order to avoid being determined as the previous mode, another mode transition lottery table having a different lottery value from the mode transition lottery table shown in FIG. 8(f) may be referred to.

In the increased section (pseudo bonus), a mode transition lottery (at the time of winning) is performed for each game (more specifically, in a game in which a winning is made in "F_Replay A" or "F_Replay B"). Specifically, the mode transition lottery table shown in FIG. 8(f) is referred to, and the destination mode is determined according to the current mode and the advantageous section winning time sub-flag. In this case, as above, in order to prevent a mode that is relatively disadvantageous than the current mode from being determined as the destination mode, the mode transition lottery table shown in (f) of FIG. 8 is based on the lottery value. Another mode transition lottery table with a different value may be referred to.

In the increasing section (pseudo bonus), a 1G consecutive lottery is performed for each game. Specifically, the 1G consecutive lottery table shown in FIG. 7(d) is referred to, and it is determined whether or not to generate a 1G consecutive lottery according to the current mode and the advantageous section winning sub-flag or the advantageous section winning sub-flag. be done. In addition, in (d) of Figure 7, "non-winning" means that 1G series will not be generated, and "winning (1G series + 1)" means that the right to generate 1G series (1G series stock) is 1 piece. It means that it is given (the 1G continuous stock counter is incremented by 1). Note that a plurality of 1G continuous stocks (up to 255) can be stocked (stored) by the 1G continuous stock counter. Therefore, a plurality of 1G continuous stocks may be awarded during one pseudo bonus. Furthermore, the 1G continuous lottery table can be configured so that a plurality of 1G continuous stocks can be awarded in one 1G continuous lottery.

When the pseudo bonus ends, if the value of the 1G continuous stock counter is 1 or more (that is, if you have 1G continuous stock), one 1G continuous stock is used up (the 1G continuous stock counter is (subtracted by 1), and the pseudo bonus will start again from the next game after the pseudo bonus ends. Note that in this case, since a pseudo bonus corresponding to the right of 1G continuous stock is started, the above-mentioned mode transition lottery is not performed. On the other hand, when the pseudo bonus ends, if the value of the 1G continuous stock counter is not 1 or more (that is, if you do not own 1G continuous stock), and if you have not won the ceiling reduction lottery described above, The number of ceiling games is set according to the current mode (in the case of end mode, it is not set because the advantageous section ends after 32 games (and is cleared accordingly), but the number of ceiling games is temporarily set here. ), the pseudo bonus ends ("pseudo bonus end" in FIG. 5), and the transition to the performance section (normal game) occurs.

In addition, if you win the ceiling shortening lottery and also have 1G continuous stock, the result of the ceiling shortening lottery will take priority, and after the pseudo bonus according to the ceiling shortening is executed, the pseudo bonus according to the 1G continuous stock will be given. Alternatively, the 1G continuous stock may be given priority, and after the pseudo bonus corresponding to the 1G continuous stock is executed, the pseudo bonus corresponding to the ceiling reduction may be executed. In the latter case, it is sufficient to separately store information that can carry forward the fact that there is ceiling shortening.

In the first gaming machine, as an example of the structure of the increase period (pseudo bonus), the structure continues for "55 games" and a maximum of 275 coins can be acquired, but the structure of the pseudo bonus is limited to this. do not have. For example, the pseudo bonus is configured as a "pseudo BB (big bonus)", and a "pseudo RB (regular bonus)" is also installed, which is a pseudo bonus that lasts for "22 games" and can earn up to 110 coins. You can do it like this. In this case, when it is decided to transfer to a pseudo bonus (grant the right) in the above-mentioned pseudo bonus transfer lottery, when the ceiling is reached, and in the 1G consecutive lottery, the type (for example, "pseudo BB") RB or "pseudo RB") may be determined with a predetermined probability (for example, in 50% increments). Note that "pseudo RB" may have a different value from "pseudo BB" (more specifically, it has lower value than "pseudo BB"), so for example, the number of consecutive games may be different from "pseudo BB". BB", but by setting the BellNavi rate (probability of notification of stop operation information) to a low value, it is possible to differentiate the maximum number of coins that can be acquired and make the value different. In addition, when starting the "pseudo RB", a reel performance in which "BAR" symbols are displayed all together on the main display window 4, or a reel performance in which "Red 7-Red 7-BAR" is displayed is performed. Just do it like this. Furthermore, the increase section is not limited to one configured as a pseudo bonus. For example, it may be configured as an AT state or an ART state in which the number of continued games (game period) can be changed.

Additionally, if the conditions for executing the limit process shown in FIG. 16 (described later) are met during the pseudo bonus, the advantageous section will be forcibly terminated (in FIG. 5, "end of advantageous section due to limit process"). ), resulting in a transition to a non-advantageous section.

In the first gaming machine, the above-described flow of the game is basically based on the premise that the game is played in a three-bet bet state. Therefore, when a game is played with two bets, for example, various drawings using (a) to (d) in FIG. 7, (e) and (f) in FIG. 8, etc. are not performed, and The number of ceiling games is also not updated. Furthermore, if a game is played with two bets during the pseudo bonus, the medals are configured not to increase in the two bet state, so the period during the pseudo bonus does not become an increasing period. That is, the first gaming machine is configured so that the player is basically at a disadvantage when playing a game with two bets.

Here, when a game is played with two bets, the lottery regarding the advantageous section (AT) (for example, (a) to (d) in FIG. 7, (e) and (f) in FIG. 8, etc.) is used. (various lotteries) and processing (for example, updating the number of ceiling games) will not be performed, but the above-mentioned advantageous section game number counter for the number of games limiter and the above-mentioned advantageous section payout number counter for the payout number limiter will be updated. It is desirable that the These limiters have the function of appropriately suppressing the gambling nature by limiting the number of games stayed in the advantageous section and the upper limit of the number of coins acquired, so even if two coins are bet, these counters will not be updated. If this is the case, there will be cases where the number of stay games and the number of coins won will exceed the upper limit of the set advantageous zone due to intervening games with two bets, and as a result, it may not be possible to appropriately suppress the gambling nature. It's to get it. Therefore, it is desirable that the limiter counter be configured to be able to be updated every game regardless of the number of bets.

Furthermore, in the first gaming machine, the above-described game flow is basically based on the premise that the game is played in a non-bonus state. Therefore, when a game is played in the bonus state (2BB state and 3BB state), various lotteries using, for example, (a) to (d) in FIG. 7, (e) and (f) in FIG. 8, etc. It will not be played, and the number of ceiling games will not be updated. In addition, if a bonus state occurs during a pseudo-bonus, the bonus state is configured as a state in which the expected increase in medals is lower than the non-bonus state (more specifically, the non-bonus state with a 3-card bet). , the period during the pseudo bonus may not be an increase period. That is, the first gaming machine is configured so that the player may be at a disadvantage if he plays the game in the bonus state.

Therefore, the first gaming machine is configured so that it is recommended to play a game with a 3-card bet between 2BB flags (in this embodiment, a 3-card bet between 2BB flags is referred to as a "recommended game"). In some cases, other states may be described as "non-recommended gaming states"). In other words, in the first gaming machine, 2BB is a bonus combination that can only be won in a 2-piece bet state, and the combination of symbols related to 2BB between the 2BB flags can only be won in a 2-piece bet state, and cannot be won in a 3-piece bet state. The configuration is such that it does not. Further, 3BB is a bonus combination that can be won only in a 3-piece bet state, and the combination of symbols related to 3BB between the 3BB flags is configured such that it can only be won in a 3-piece bet state and not in a 2-piece bet state. Furthermore, there is no case where 3BB is won between 2BB flags, and there is no case where 2BB is won between 3BB flags.

Then, in the first gaming machine, using these configurations, for example, after winning 2BB in a 2-bet bet state between non-flags (without winning 2BB) and placing it between 2BB flags, a 3-bet bet state is made. If you play the game with , you can play the game in the above-mentioned recommended gaming state without worrying about whether or not you will win the bonus combination.

As described above, in the first gaming machine, the ceiling reduction lottery is performed during the pseudo bonus. Here, looking at the ceiling reduction lottery table shown in FIG. 8(e), when the current mode is one of the guarantee mode, heaven A mode, heaven B mode, and heaven C mode, 1 The probability of winning the ceiling reduction lottery is /8 (32/256), while the ceiling reduction lottery is not won in other modes. That is, in the case of a mode in which the number of ceiling games is "32 games", the "32 games" may be shortened to "0 games", and in the case of a mode in which the number of ceiling games is greater than that, This prevents the number of ceiling games from being shortened.

Note that even in a mode where the number of ceiling games is more than "32 games", the probability that the number of ceiling games is greater than "32 games" is lower (for example, 1/64) than in a mode where the number of ceiling games is "32 games". may be determined to be shortened.

Further, the manner in which the number of ceiling games is shortened is not limited to the above-mentioned method. For example, if you shorten "32 games" to a smaller number of predetermined games (0 to 31 games), the same effect can be achieved, so when you win the ceiling shortening lottery, the number of shortened games will be further determined. Alternatively, the number of games to be shortened may be determined in advance in the ceiling shortening lottery.

Moreover, the opportunity for performing the ceiling shortening lottery is not limited to the above-mentioned one. For example, during a pseudo bonus, a ceiling reduction lottery may be performed for each game. In addition, in the advantageous section (normal game), when the current mode is one of the guarantee mode, heaven A mode, heaven B mode, and heaven C mode, ceiling shortening lottery will be performed for each game. You can also do this. In these cases, the advantageous section winning time sub-flag and the advantageous section winning time sub-flag may be referred to to determine whether or not to win the ceiling shortening lottery.

Further, as described above, in the first gaming machine, a 1G consecutive lottery is performed during the pseudo bonus. Here, looking at the 1G continuous lottery table shown in FIG. 7(d), it is shown that 1G continuous stock may be awarded regardless of which mode the current mode is. In other words, the right to continue the pseudo bonus can be granted regardless of whether the mode has a ceiling of 32 games or not.

Note that the manner in which the rights are granted is not limited to the above. For example, in a mode where the number of ceiling games is "32 games", 1G continuous lottery is not performed considering that a ceiling reduction lottery will be performed, and in a mode where the number of ceiling games is greater than "32 games". By allowing the 1G consecutive lottery to be performed when , the gambling nature of the game may be prevented from becoming excessively high.

Moreover, the opportunity for performing the 1G lottery is not limited to the above-mentioned one. For example, the 1G continuous lottery may be performed even in an advantageous section (performance section) other than the pseudo bonus, and the 1G continuous stock stocked as a result may be used up in the next pseudo bonus.

Although illustrations are omitted in FIGS. 5 to 8, in the first gaming machine, when the current mode is the heaven mode at the start of the pseudo bonus or during the pseudo bonus, the game machine is in an advantageous state. A special bonus performance to suggest something is executed with a predetermined probability. Therefore, when the special bonus performance is executed, it is possible to make the player expect that the ceiling reduction lottery will be executed. Further, this special bonus performance may be executed with a 100% probability when the ceiling shortening lottery is won. In this way, for example, if a special bonus effect is executed at the start of a pseudo-bonus, it will be suggested that you are at least staying in heaven mode, and there is also the expectation that you may have won the ceiling shortening lottery. It can make you feel. Further, this special bonus performance may be executed with a predetermined probability or with a 100% probability even when a 1G consecutive lottery is won during the pseudo bonus. In this way, (1) Heaven mode only, (2) Heaven mode + ceiling shortening winning, (3) heaven mode + 1G consecutive winning, (4) heaven mode + ceiling shortening winning + 1G consecutive winning, (5) 1G consecutive winning. Various possibilities such as winning only can be suggested, and the interest of the game can be improved.

In this way, in the first gaming machine, if it is determined that the advantageous condition (for example, pseudo bonus) will be controlled again within a predetermined period (for example, 32 games) after the end of the advantageous condition (for example, pseudo bonus), , in the case of heaven mode), the period may be further shortened. Therefore, even if the playing period of a series of advantageous sections is limited (for example, when limit processing is executed), the player It is possible to prevent a decrease in interest in the game by allowing the game to be played in a state where the degree of advantage is as high as possible.

Furthermore, in the first gaming machine, even if it is not certain that the advantageous state will be controlled again within a predetermined period after the end of the advantageous state (for example, in the case of the end mode), the rights (for example, , 1G continuous stock) may restart the advantageous state, so it is possible to increase the player's expectations and improve the interest in the game.

Furthermore, although not shown in FIGS. 5 to 8, in the first gaming machine, when a "confirmed combination" is determined as a sub-flag at the time of winning in an advantageous section (i.e., "F_confirmed cherry" or "F_ ``Reach roll'' is determined as an internal winning combination), and if it is determined to shift to heaven C mode as a result of the mode transition lottery described above, the probability is 1/2 (this probability is arbitrary). ), a special rock performance can be performed. Furthermore, even if the advantageous section winning sub-flag "Middle Che" is determined (that is, when "F_middle cherry" is determined as the internal winning combination), the player may also select the "Confirmed winning combination" as the advantageous section winning sub-flag. ” is determined, so if the sub-flag “Middle Che” is determined at the time of winning an advantageous section, it is the same as when “Confirmed hand” is determined as the sub-flag at the time of winning the advantageous section. Similarly, a special lock performance may be made possible.

Here, since the "confirmed hand" is a hand that also confirms the transition to a pseudo bonus (see (c) in FIG. 7), when the special lock effect is executed, the player can transfer to the pseudo bonus and transition to heaven C mode. It is now possible to recognize that there has been a game, and it has become very interesting for players. The special lock performance is, for example, configured as a performance in which game operations (stop operations) are disabled for approximately 20 seconds at the start of the game. During this time, a special reel effect may be performed in which each reel vibrates or rotates in reverse, or a special video etc. that is not normally displayed may be displayed on the main effect display section 21. You may also do so. Also, special music that is not normally output may be output. Of course, it is also possible to produce effects by combining these. In addition, although the game operation is not invalidated, these effects can be made to continue until the player performs the next game operation (in other words, the effect can be executed to the end or canceled midway through). It is also possible to leave the decision of whether to proceed with the game to the player).

However, in the first gaming machine, as shown in FIG. 16, which will be described later, for example, even if you stay in heaven C mode, the advantageous section may be forcibly terminated by executing the limit process. , it may be undesirable to perform the above-mentioned special lock effect many times.

Therefore, in the first gaming machine, the special lock effect is executed only once within the same series of advantageous sections. Specifically, within a series of advantageous sections, if it is decided to execute a special lock effect for the first time, the special lock effect will be executed, but after that, within the same series of advantageous sections, the same conditions will be applied. To control so that a special lock performance is not executed even if it is established. In addition, the method is that once a special lock effect is executed, information indicating that effect is stored, and if the information is stored in the same series of advantageous sections thereafter, the special lock effect is not activated in the first place. The decision as to whether or not to execute the performance may not be made, or the decision may be made, but if the information is stored, the result of the decision indicates that the performance will be executed. may also be rewritten to indicate that it will not be executed. Then, the stored information may be cleared when the advantageous section ends.

Note that the manner in which the execution of the special lock effect is restricted is not limited to the above-mentioned one. For example, the upper limit of the number of times the special lock effect can be executed may be set as "twice" or "three times" instead of "one time". That is, the execution of the special lock effect is limited, but the upper limit may be set as a plurality of times. This can be set as appropriate depending on the expected value of balls to be rolled out per special lock effect.

Furthermore, the conditions under which it is determined whether or not the special lock effect is to be executed are not limited to those described above. In other words, in the above, a mode transition is performed upon winning a "confirmed role", and a decision is made as to whether or not a special lock effect will be executed on the condition that the mode is Heaven C mode. However, for example, there are cases where the game enters heaven C mode due to an opportunity other than winning the "confirmed role" (see (f) in Figure 8), so the special lock effect is executed in these cases as well. A special lock effect will be executed with a predetermined probability (the probability may be the same as that triggered by winning a "determined role", or it may be a different probability). It may be determined that the

Furthermore, for example, upon winning a "determined role", it is first decided whether or not a special lock performance will be executed, and if it is decided that a special lock performance will be executed, the heaven It may be possible to shift to C mode. In other words, the special lock performance may be executed in response to the decision to move to heaven C mode, or the transition to heaven C mode may be performed in response to the decision to perform the special lock performance. It may also be possible to shift to .

Further, for example, the degree of progress of the game during the advantageous section may be adopted as the condition for determining whether or not the special lock performance is to be executed. For example, when the value of the advantageous section game number counter or control game number counter described below is less than "750", or when the value of the advantageous section payout number counter or control payout number counter described later is less than "1201", , When it is determined whether or not to execute the special lock effect as described above, and the value of the advantageous section game number counter or the control game number counter described below becomes "750" or more, or When the value of the section payout number counter or the control payout number counter becomes "1201" or more, a decision as to whether or not a special lock performance will be executed is made not to be made in the same series of advantageous sections thereafter. You can also do that.

In this way, in the first gaming machine, the gaming period of a series of advantageous sections is limited to a fixed period (see FIG. 16, which will be described later). In the same series of advantageous sections, even if control information that is highly advantageous to the player (for example, Heaven C mode) is set multiple times, special effects (for example, special lock effects) are set each time. controlled so that it does not occur. Therefore, while suppressing the gambling nature of the game from becoming excessively high, it is possible to prevent the game from becoming less interesting.

In addition, in the first gaming machine, within a series of advantageous sections, it is determined that the winning of a specific winning combination (for example, a "determined winning combination") will trigger an advantageous state (for example, a pseudo bonus), and , control information that is highly advantageous to the player (for example, heaven C mode) may be set. Even if such a case occurs multiple times within the same series of advantageous sections, the control is such that special effects (for example, special lock effects) are not performed each time. Therefore, while suppressing the gambling nature of the game from becoming excessively high, it is possible to prevent the game from becoming less interesting.

Furthermore, in the first gaming machine, it is possible to determine secondary information (for example, advantageous section winning sub-flag) according to the determined internal winning combination, and secondary information (for example, an advantageous section winning sub-flag) according to the combination of displayed symbols. For example, it is possible to determine whether to grant an advantageous state (for example, a pseudo bonus) in which information regarding the player's stop operation is notified, depending on the determined secondary information. It is assumed that it can be determined.

In this way, in the first gaming machine, it is possible to give a sense of expectation regarding the provision of an advantageous state not only when an internal winning combination is determined but also when a combination of symbols is displayed. It is possible to diversify the gameplay regarding giving.

In addition, the first gaming machine manages both the information corresponding to the determined internal winning combination and the information corresponding to the displayed symbol combination as common secondary information. It is possible to suppress an increase in the control load and amount of information related to provision.

Further, in the first gaming machine, when the betted gaming value is the first amount (for example, 3 coins), the first special prize (for example, 3BB) can be won, while the second special prize (for example, , 2BB) cannot be won. Further, when the betted game value is the second amount (for example, 2 coins), the second special winning combination is made possible to win, while the first special winning combination is not made possible to win. In addition, when winning a specific combination (for example, "F_Replay A"), if it is in the first special permission state (for example, between 3BB flags), a predetermined symbol combination (for example, "Rip to the right") is displayed, and If it is in the 2 special permission state (for example, between 2BB flags), it is possible to display a combination of specific symbols (for example, "Parallel Rip") (see FIG. 15, which will be described later).

In the first gaming machine, different secondary information can be determined when a predetermined symbol combination is displayed and when a specific symbol combination is displayed. In other words, in the first gaming machine, even if the same specific combination is determined, the content of the decision regarding the granting of an advantageous state can be changed depending on which special permission state is in effect. It is possible to further diversify the gameplay while suppressing an increase in the control load and amount of information regarding the provision of states.

Further, in the first gaming machine, it is possible to determine whether or not to give an advantageous state at least when a specific winning combination is won and a specific combination of symbols is displayed.

Here, in the first gaming machine, since both the predetermined symbol combination and the specific symbol combination are symbol combinations related to re-gaming, it is considered that re-gaming is activated no matter which one is displayed. The same benefits will be granted.

Note that the manner in which the same benefits are provided is not limited to the above. For example, the specific winning combination is configured as a specific small winning combination that is associated with the granting of gaming value. If you win a specific small role, for example, if you are in the first special permission state, you will receive 1 coin (this value is arbitrary and may be any other value below the betted gaming value, or The second special permission In this case, a combination of specific symbols that gives the same number of gaming values as when a combination of predetermined symbols is displayed (a combination of symbols that gives a gaming value equivalent to "parallel reply") is displayed. You can.

In addition, both the combination of predetermined symbols and the combination of specific symbols are combinations of symbols that are "missing" (however, in order to make it possible to decide whether or not to give an advantageous state, a symbol that is different from the case of pure "missing") A combination of symbols may be configured as a combination of distinguishable symbols. Even in this case, the value remains the same.

In this way, in the first gaming machine, even if the same specific combination is determined, the content of the decision regarding the granting of an advantageous state can be varied depending on which special permission state is in place. , it is possible to diversify the gameplay while suppressing an increase in the control load and amount of information regarding the provision of advantageous states. In addition, in games where a specific combination has been determined, the same benefits are granted regardless of which special permission state the player is in, so even if the gameplay is changed, the player is not directly disadvantaged. You can prevent it from getting covered.

In addition, in the first gaming machine, when a specific winning combination is won, a specific combination of symbols can be displayed when a stop operation is performed in a specific manner in the second special permission state, and a specific combination of symbols can be displayed. It may be configured such that it is not possible to display a specific combination of symbols when a stop operation is not performed in the mode.

Then, it may be possible to determine whether or not to give an advantageous state at least when a specific combination is won and a specific combination of symbols is displayed. If a specific combination is determined as an internal winning combination, it is possible to make the degree of advantage regarding the granting of an advantageous state different depending on when a combination of specific symbols is displayed and when a combination of specific symbols is not displayed. good.

In addition, if you win a specific combination, if you are in the first special permission state, a predetermined combination of symbols will be displayed regardless of the stop operation mode, and if you are in the second special permission state, you will be able to display the stop operation in a specific manner. When the stop operation is performed, a specific combination of symbols may be displayed, and when the stop operation is not performed in a specific manner, a predetermined symbol combination may be displayed.

In this case, the specific combination is determined when the timing of the stop operation is appropriate on at least one reel (in this embodiment, this may be explained as "press position ○", "press position correct", etc.). When a specific combination of symbols is displayed and the timing of the stop operation is not appropriate (in this embodiment, this may be explained as "pressed position x", "incorrect pressed position", etc.), the specified symbol combination is displayed. It can be configured as displayed. As a result, the degree of advantage regarding the granting of an advantageous state can be changed depending on (the timing of) the player's stop operation, which allows the player to concentrate more on the game and improves the interest of the game. can.

In addition, as mentioned above, the specific winning combination can also be configured as a specific small winning combination, and in this case, on at least one reel, if the timing of the stop operation is appropriate (when the pressed position is ○), the specific symbol will be displayed. A combination is displayed and a predetermined number of gaming values are awarded, and if the timing of the stop operation is not appropriate (when the pressed position is x), a predetermined combination of symbols is displayed and a specific number of gaming values are awarded. can do. In this case, the predetermined number may be the same as the specific number (that is, the same benefit). Further, a predetermined number may be awarded more gaming value than a specific number. Furthermore, the predetermined number may be awarded less gaming value than the specific number. Further, at least one of the specific symbol combination and the predetermined symbol combination may be used as a symbol combination when a failure occurs. That is, either the predetermined number or the specific number may be set to "0". As a result, it is possible to not only change the degree of advantage regarding the granting of an advantageous state due to (the timing of) the player's stop operation, but also to change the content of direct benefits, so that the player This allows the player to concentrate more on the game, further diversifies the gameplay, and improves the interest of the game.

Furthermore, if there is only one type of specific combination, the timing at which the timing of the stop operation is appropriate is also limited, so it is desirable to provide a plurality of specific combinations with different timings at which the timing of the stop operation is appropriate. For example, on one reel, when the timing of the stop operation is the first timing, the stop operation becomes an appropriate stop operation and a specific symbol combination is displayed, and when the timing of the stop operation is other than the first timing, the stop operation is appropriate. When the first specific combination is not and the combination of specific symbols is not displayed, and the timing of the stop operation is a second timing different from the first timing, the appropriate stop operation is performed and the combination of specific symbols is displayed. , and when the timing is other than the second timing, the combination of specific symbols is not displayed without an appropriate stop operation. What is the second specific combination, and when the timing of the stop operation is the first timing and the second timing? When the third timing is different, the stop operation is appropriate and the combination of specific symbols is displayed, and when the timing is other than the third timing, the stop operation is not appropriate and the combination of specific symbols is not displayed. A third specific winning combination is provided, and these winnings may be won with the same probability of winning.

In addition, in this case, the specific combination of symbols is displayed when the batting order is appropriate (in the case of correct pressing order), and the specified combination of symbols is displayed when the batting order is not appropriate (in the case of incorrect pressing order). It can be configured as displayed. As a result, it is possible to change the degree of advantage regarding the granting of an advantageous state due to (the procedure of) the player's stop operation, which allows the player to concentrate more on the game and improves the interest of the game. can.

In addition, the specific combination can be configured as a specific small combination as described above, and in this case, when the batting order is appropriate (in the case of correct pressing order), a combination of specific symbols is displayed and a predetermined number of games are played. It can be configured such that when a value is given and the batting order is not appropriate (in the case of an incorrect pressing order), a predetermined combination of symbols is displayed and a specific number of game values are given. In this case, the predetermined number may be the same as the specific number (that is, the same benefit). Further, a predetermined number may be awarded more gaming value than a specific number. Furthermore, the predetermined number may be awarded less gaming value than the specific number. Further, at least one of the specific symbol combination and the predetermined symbol combination may be used as the symbol combination when a missed spot occurs. That is, either the predetermined number or the specific number may be set to "0". As a result, not only can the degree of advantage regarding the granting of an advantageous state be changed due to the player's stop operation (the procedure), but also the details of the direct benefits can be changed, so the player This allows the player to concentrate more on the game, further diversifies the gameplay, and improves the interest of the game.

Furthermore, if there is only one type of specific combination, the appropriate batting order will be limited, so it is desirable to provide a plurality of specific combinations with different appropriate batting orders. For example, when it is the first stop on the left, the appropriate stop operation is performed and a specific combination of symbols is displayed, and when it is the first stop in the center or right, the appropriate stop operation is not performed and the combination of specific symbols is not displayed. When it is the 1st specific combination and the middle 1st stop, the appropriate stop operation is performed and a combination of specific symbols is displayed, and when it is the left/right 1st stop, the appropriate stop operation is not performed and the combination of specific symbols is displayed. When the combination is the 2nd specific combination that is not displayed and the 1st stop on the right, it becomes an appropriate stop operation and a combination of specific symbols is displayed, but when it is the 1st stop on the left or middle, it is not an appropriate stop operation. A combination of specific symbols is provided with a third specific combination that is not displayed, and these may be set to win with the same probability of winning.

Up to this point, in the unit game in which a specific winning combination has been won, due to the stop operation mode (at least one or both of the timing of the stop operation and the batting order), the transition judgment process from an unfavorable section to an advantageous section, or an advantageous section As described above, the determination process regarding the granting of an advantageous state (including the pseudo bonus transition lottery, mode transition lottery, and other processes for changing the advantage of the gaming situation in the advantageous section) will be changed. Among these, changes that are relatively disadvantageous to the player (which may result in disadvantage) can be regarded as the above-mentioned penalty. Therefore, when such a change occurs, a configuration may be adopted in which an arbitrary effect (warning notification) can be generated to call attention.

In addition, in the first gaming machine, when a specific winning combination is won, there is a higher possibility that an advantageous state will be given when a combination of specific symbols is displayed than when a combination of predetermined symbols is displayed. It has become. In other words, assuming that 3 coins are bet, the second special permission state (for example, between 2BB flags) is a state in which the granting of an advantageous state is more preferential than the first special permission state (for example, between 3BB flags). It is.

In addition, in the first gaming machine, if you win a predetermined combination (for example, "Push Order Bell B" described later), if you are in the first special permission state, you can combine the awarded symbols (for example, 8 pieces payout) regardless of the batting order. On the other hand, in the second special permission state, if the batting order is the predefined correct pressing order, the given symbol combination will be displayed, but the batting order is predefined. If it is not the correct pressing order, the combination of awarded symbols will not be displayed and no gaming value will be awarded, or a smaller amount of gaming value will be awarded than if the combination of assigned symbols had been displayed. It is configured so that a combination of symbols (for example, a combination of symbols that results in one payout) is displayed. That is, unless the operation of the advantageous state is taken into consideration, the first special permission state is a state in which the granting of gaming value is given more preferential treatment than the second special permission state.

In other words, even if the player is in a non-recommended gaming state, if the player plays a game with a bet of 3 cards between the 3BB flags, the probability of giving an advantageous state will not be given preferential treatment, but the gaming value will be increased when the advantageous state is not activated. Since the granting probability is given preferential treatment, the game can be played with a relatively small difference in slope value between when the advantageous state is activated and when it is not activated. In this way, a state in which the player's gaming value is unlikely to decrease, although the possibility that the player can rapidly increase the gaming value is reduced, can be defined, for example, as a "stable state."

On the other hand, if the player plays a game in the recommended gaming state, the probability of granting an advantageous state will be treated favorably, but the probability of granting gaming value when the favorable state is not activated will not be treated favorably, so the favorable condition will not be activated. The game can be played in a state where the difference in slope value between when it is activated and when it is not activated is relatively large. In this way, a state in which there is a high possibility that the player will be able to rapidly increase the gaming value, but the player's gaming value is likely to decrease can be defined, for example, as a "rough sea state."

Here, the method of creating two states, a stable state and a rough sea state, is not limited to the above-mentioned method. For example, in the "stable state", in the above-mentioned pseudo-bonus transition lottery, the pseudo-bonus transition probability is made higher than in the "rough sea state", while in the above-mentioned mode transition lottery, the transition probability of heaven mode is made higher than in the "rough sea state". lower. In addition, in the "rough sea state", in the above-mentioned pseudo-bonus transition lottery, the transition probability of the pseudo bonus is lower than in the "stable state", while in the above-mentioned mode transition lottery, the transition probability of heaven mode is lower than in the "stable state". enhance In this way, it is possible to create a state in which it is easy to hit a pseudo bonus for the first time in a "stable state" but difficult to hit consecutive games, and in a "rough sea state" it is difficult to hit a pseudo bonus for the first time, but it is easy to win consecutive games. This situation can be created. As for the stop control of the predetermined combination, as described above, it may be changed between 2BB flags and between 3BB flags, or it may be different from this (that is, no preferential treatment is given between 3BB flags).

[5-2. Design layout configuration of first gaming machine]
Next, with reference to FIG. 9, the symbol arrangement of the first gaming machine will be explained. FIG. 9 is a diagram showing an example of a symbol arrangement table of the first gaming machine. As shown in FIG. 9, in the first gaming machine, "Red 7", "BAR", "Replay", "Bell", "Watermelon", "Cherry", "Red Blank", "Yellow Blank", " Ten types of symbols, ``White Blank 1'' and ``White Blank 2,'' are arranged at the positions shown in FIG. 9 on each reel 3L, 3C, and 3R. Further, as shown in the symbol code table, symbol codes 1 to 10 are assigned to each symbol.

[5-3. Internal winning combination configuration of first gaming machine]
Next, the internal winning combination configuration of the first gaming machine will be explained with reference to FIGS. 10 to 15. FIG. 10 is a diagram showing an example of an internal lottery table of the first gaming machine. Further, FIGS. 11 to 14 are diagrams showing examples of symbol combination tables of the first gaming machine. Further, FIG. 15 is a diagram showing an example of the correspondence between the internal winning combination, the stop operation mode, the display combination, etc. of the first gaming machine. That is, in the following, which symbol is selected depending on the type of internal winning combination drawn in the first gaming machine and the stop operation mode (i.e., batting order, stop operation timing, etc.) when each internal winning combination is won. We will explain whether the combinations (which can also be referred to as display combinations, winning combinations, stop display modes, display results, etc.) are displayed.

First, in the first gaming machine, in an internal lottery process (see FIG. 26) described later, each internal winning combination shown in FIG. 10 is won with the probability shown in FIG. 10 (lottery value/probability denominator: 65536). The symbol combinations that are permitted to be displayed when each internal winning combination is won are as shown in "Corresponding symbol combinations" in FIG. In addition, in FIGS. 11 to 14, "BB" indicates a combination of symbols related to a bonus role, "REP" indicates a combination of symbols related to a replay role, and "FRU" indicates a combination of symbols related to a minor role. It shows.

“F_2BB” can be determined as an internal winning combination when a game is played with a 2-card bet in a non-bonus state (more specifically, between non-flags), while when a game is played with a 3-card bet. The structure is such that if the winning combination is determined to be an internal winning combination, it will not be determined as an internal winning combination. In a game in which "F_2BB" wins in a 2-bet state, or in a game in which "F_2BB" is a "miss" between the 2BB flags, "BB01" will be displayed if the pressed position is ○ for each reel, and the 2BB state (based on 2BB) will be displayed. (bonus state). On the other hand, even if it is between two BB flags, "BB01" will not be displayed in a three-bet bet state.

“F_3BB” can be determined as an internal winning combination when a game is played with a 3-card bet in a non-bonus state (more specifically, between non-flags), while it can be determined as an internal winning combination when a game is played with a 2-card bet. The structure is such that if the winning combination is won, it will not be determined as an internal winning combination. In a game in which "F_3BB" wins in a 3-bet state, or in a game in which "F_3BB" is a "miss" between the 3BB flags, if the pressed position is ○ for each reel, "BB02" will be displayed, and the 3BB state (based on 3BB) will be displayed. (bonus state). On the other hand, even if it is between 3 BB flags, "BB02" will not be displayed in a 2-bet bet state.

In addition, in the 2BB state and the 3BB state, the lottery value in the "bonus state" column in FIG. 10 is referred to and the internal winning combination is determined (the number of coins that can be started is only 3 coins). During the 2BB state and 3BB state, the RB, which is a first class special accessory, is always controlled to be in operation (RB state). In the RB state, control is repeated such that when two winnings occur or two games are played after activation, the RB state is once terminated and activated again. Furthermore, in the first gaming machine, the end condition for the 2BB state is stipulated that more than one medal is paid out in the 2BB state, and the end condition for the 3BB state is defined as that more than 176 medals are paid out in the 3BB state. It is stipulated that the amount has been paid out.

Here, when the 2BB state or the 3BB state ends, special mode transition processing is performed. For example, if the mode in which you entered the bonus state (same as when the bonus state ends, as no mode transition occurs during the bonus state), i.e., the current mode, is "start mode", then the transition destination The mode is "start mode". Further, if the current mode is one of "normal A mode", "normal B mode", "heaven preparation mode", and "chance mode", the destination mode will be "normal A mode". Further, if the current mode is either "end A mode" or "end B mode", the destination mode will be "end A mode". Furthermore, if the current mode is one of "guarantee mode," "heaven A mode," "heaven B mode," and "heaven C mode," the destination mode will be "guarantee mode."

“F_Replay A” is configured to be determined as an internal winning combination regardless of the number of bets in a non-bonus state. If it is determined as an internal winning combination, between non-flags and between 2BB flags, one of "REP64" to "REP72" is selected regardless of the stop operation mode (these are "replay" symbols in a straight line in the lower row or in a straight line in the middle row). Since they are displayed, they can be collectively referred to as "parallel reps." Also, "REP64" to "REP71" can be collectively referred to as "lower reps," and "REP72" is a "middle rep." "Reply") is displayed and a replay is granted. On the other hand, between the 3BB flags, regardless of the stop operation mode, "REP73" (this can be called "replay" as it displays the "replay" symbol upward to the right) will be displayed and a replay will be granted.

“F_Replay B” is configured to be determined as an internal winning combination regardless of the number of bets in a non-bonus state. Note that in a 3-card bet state, it can be determined as an internal winning combination, but in a 2-card bet state, it can be configured so that it is not determined as an internal winning combination. If it is determined as an internal winning combination, "parallel reply" will be displayed regardless of the stop operation mode in any state and a replay will be granted.

“F_Cherry” is configured to be determined as an internal winning combination in a non-bonus state regardless of the number of bets. Note that in a 3-card bet state, it can be determined as an internal winning combination, but in a 2-card bet state, it can be configured so that it is not determined as an internal winning combination. If it is determined as an internal winning combination, in a 2-card bet state, a "middle rep" is displayed regardless of the stop operation mode, and a replay is awarded. In the 3-bet bet state, if the pressed position is ○ for at least the left reel 3L, one of "REP28", "REP60" to "REP63" will be displayed (these are for displaying the "cherry" symbol at the bottom of the left reel 3L). Therefore, these can be collectively referred to as "Cherry Rip") is displayed, and a replay is granted. On the other hand, if the pressed position is x, other replies (for example, "REP57" to "REP59") are displayed, and a replay is granted.

“F_Confirmed Cherry” is configured to be determined as an internal winning combination in a non-bonus state regardless of the number of bets. Note that in a 3-card bet state, it can be determined as an internal winning combination, but in a 2-card bet state, it can be configured so that it is not determined as an internal winning combination. If it is determined as an internal winning combination, in a 2-card bet state, a "middle rep" is displayed regardless of the stop operation mode, and a replay is awarded. In the 3-card bet state, if the pressing order is any one of "batting order 1" to "batting order 4", if the pressed position is ○ for at least the left reel 3L, one of "REP42" to "REP56" (these are The "Cherry" symbol is displayed at the bottom of the left reel 3L, and since symbols such as "REP42" that can increase the player's expectations on other reels are also displayed, these are ) is displayed and a replay is granted. On the other hand, if the pressed position is x, other replies (for example, the above-mentioned "Cherry Rep" and "REP29" to "REP41") are displayed, and a replay is granted. Furthermore, if the pressing order is either "batting order 5" or "batting order 6", "middle row rep" is displayed regardless of the stop operation mode, and a replay is given.

“F_middle cherry” is configured to be determined as an internal winning combination in a non-bonus state regardless of the number of bets. Note that in a 3-card bet state, it can be determined as an internal winning combination, but in a 2-card bet state, it can be configured so that it is not determined as an internal winning combination. If it is determined as an internal winning combination, in a 2-card bet state, a "middle rep" is displayed regardless of the stop operation mode, and a replay is awarded. In the 3-card bet state, if the pressing order is any of "batting order 1" to "batting order 4", if the pressed position is ○ for at least left reel 3L, one of "REP15" to "REP19" (these are Since the "cherry" symbol is displayed in the middle row of the left reel 3L, these can be collectively referred to as "middle row cherry reps"), and a replay is awarded. On the other hand, if the pressed position is x, other replies (for example, "REP20" to "REP27") are displayed, and a replay is granted. Furthermore, when the pressing order is either "batting order 5" or "batting order 6", "middle row rep" is displayed regardless of the stop operation mode, and a replay is given.

“F_Reach” is configured to be determined as an internal winning combination in a non-bonus state, regardless of the number of bets. Note that in a 3-card bet state, it can be determined as an internal winning combination, but in a 2-card bet state, it can be configured so that it is not determined as an internal winning combination. If it is determined as an internal winning combination, in a 2-card bet state, a "middle rep" is displayed regardless of the stop operation mode, and a replay is awarded. In the 3-card bet state, if the pressing order is any of "batting order 1" to "batting order 4", any of "REP01" to "REP14" will be pressed regardless of the stop operation mode (these are customary for players to It is configured as a combination of symbols that can definitively notify (or suggest) a transition to an advantageous state, and these can be collectively referred to as "reach eye reps") is displayed, and replay is possible. Granted. Furthermore, when the pressing order is either "batting order 5" or "batting order 6", "middle row rep" is displayed regardless of the stop operation mode, and a replay is given.

“F_Watermelon” is configured to be determined as an internal winning combination in a non-bonus state regardless of the number of bets. If it is determined as an internal winning combination, if the pressed position is ○ for each reel, one of "FRU10" to "FRU12" (these are "watermelon" symbols displayed side by side, so (which can be collectively referred to as "Watermelon") is displayed, and if the bet is on 3 medals, three medals are paid out, and if the bet is on 2 medals, 2 medals are paid out. On the other hand, if the pressed position is ×, either "FRU08" or "FRU09" (these can be collectively referred to as "watermelon spills" because the "watermelon" symbols are not displayed side by side) is displayed and one medal is paid out. In addition, in the case of the pressed position x, it is also possible to configure so that a missed medal occurs and no medals are paid out.

"F_Bell123A1", "F_Bell123A2", "F_Bell132A1", "F_Bell132A2", "F_Bell213A1", "F_Bell213A2", "F_Bell231A1", "F_Bell231A2", "F_Bell Bell 312A1", "F_Bell 312A2", "F_Bell 321A1", and "F_Bell 321A2" are configured to be determined as internal winning combinations in a non-bonus state regardless of the number of bets. Note that these can be collectively referred to as "push order bell A."

As shown in Figure 15, "Press Order Bell A" is a 6-option push order minor combination (any one of "Batting Order 1" to "Batting Order 6" is the correct pressing order). If the winning combination is determined as an internal winning combination, and if the stop operation is performed in the corresponding correct pressing order, "lower right bell" ("FRU03"), "upper bell" ("FRU01" and "FRU02") ), "middle bell" ("FRU04"), "right rising bell" ("FRU05"), "Koyama bell" ("FRU06"), and "lower bell" ("FRU07"). is displayed, and if the bet is 3 medals, 8 medals are paid out, and if the bet is 2 medals, 2 medals are paid out. On the other hand, if the stop operation is not performed in the corresponding correct pressing order, if the first stop operation is correct, the remaining stop operations will have a 1/2 probability of being pressed at the pressed position ○, and the pressed position ○ If so, which one of the winning "1-card combinations" ("FRU13" to "FRU116") is displayed and one medal is paid out. On the other hand, if the pressed position is x, medals will be missed and no medals will be paid out. In addition, if the first stop operation is not correct, the remaining stop operations have a probability of 1/8 that the pressed position will be ○, and if the pressed position is ○, which one of the winning "1-card combinations" will be displayed. , one medal is paid out. On the other hand, if the pressed position is x, medals will be missed and no medals will be paid out.

"F_Bell123B1", "F_Bell123B2", "F_Bell132B1", "F_Bell132B2", "F_Bell213B1", "F_Bell213B2", "F_Bell231B1", "F_Bell231B2", "F_Bell ``Bell 312B1'', ``F_Bell 312B2'', ``F_Bell 321B1'', and ``F_Bell 321B2'' are configured to be determined as internal winning combinations regardless of the number of bets in a non-bonus state. Note that these can be collectively referred to as "push order bell B."

As shown in FIG. 15, "Push Order Bell B" is not a push order minor combination between the 3BB flags in the 2-bet bet state and the 3-bet bet state. If it is decided as an internal winning combination, one of the above-mentioned "bells" will be displayed regardless of the stop operation mode, and if the bet is 3 medals, 8 medals will be paid out, and if the bet is 2 medals, 2 medals will be paid out. A number of medals will be paid out.

In addition, as shown in FIG. 15, the "push order bell B" is not pressed in states other than between the 3BB flags in the 3-bet state (between non-flags in the 3-bet state, and between the 2BB flags in the 3-bet state). If the winning combination is decided as an internal winning combination, and if the stop operation is performed in the corresponding correct pressing order, one of the above-mentioned "bells" will be displayed and 8 medals will be displayed. paid out. On the other hand, if the stop operation is not performed in the corresponding correct pressing order, if the first stop operation is correct, the remaining stop operations will have a 1/2 probability of being pressed at the pressed position ○, and the pressed position ○ If so, which one of the winning "one-card combinations" is displayed and one medal is paid out. On the other hand, if the pressed position is x, medals will be missed and no medals will be paid out. In addition, if the first stop operation is not correct, the remaining stop operations have a probability of 1/8 that the pressed position will be ○, and if the pressed position is ○, which one of the winning "1-card combinations" will be displayed. , one medal is paid out. On the other hand, if the pressed position is x, medals will be missed and no medals will be paid out.

The "F_RB combination of 8 cards" is configured to be determined as an internal winning combination in the bonus state. When it is determined as an internal winning combination, one of the above-mentioned "bells" is displayed regardless of the stop operation mode, and eight medals are paid out.

The "1 piece F_RB combination" is configured to be determined as an internal winning combination in the bonus state. If it is determined as an internal winning combination, one of the above-mentioned "1-card combinations" (more specifically, "FRU117" to "FRU120" are added) will be displayed regardless of the stop operation mode, and 1-card combination will be displayed. medals will be paid out.

Note that the internal lottery table shown in FIG. 10, the symbol combination tables shown in FIGS. 11 to 14, and the correspondence between the internal winning combination, stop operation mode, display combination, etc. shown in FIG. The present invention is not limited to the above embodiments.

For example, in the first gaming machine, in a 2-bet state where "BB01" can be displayed when the result is a pure "loss", when "BB01" is missed and becomes a "loss", "BB02" can be displayed. In a 3-bet state, when you miss "BB02" and become a "miss", when you become a "miss" due to a 3-bet state between 2BB flags, when a 2-bet state occurs between 3BB flags A "miss" may occur in various situations, such as when a "miss" occurs due to this, or when a "miss" occurs due to a "small winning combination" being missed. Therefore, in order to vary the symbol combinations that are displayed as "lost" in some or all of these cases, these different symbol combinations are defined in advance in the symbol combination table, and the determined internal winning combination is By allowing these to be displayed as "corresponding symbol combinations" depending on the situation, it is also possible to vary the symbol combinations related to "missing" displayed depending on the state or the like.

[5-4. Limit processing configuration of first gaming machine]
Next, with reference to FIG. 16, the limit processing configuration of the first gaming machine will be described. FIG. 16 is a diagram for explaining an example of each limit process in the first gaming machine. As shown in FIG. 16, in the first gaming machine, normal limit processing (number of games), normal limit processing (number of payouts), special limit processing (number of games), special limit processing (number of payouts), semi-limit processing ( Each limit process (number of games) and semi-limit process (number of payouts) are executed. Note that this is an example of limit processing that can be executed, and limit processing other than these limit processing can be executed, or some of these limit processing can be executed. You can also prevent it from happening.

The normal limit process (number of games) is executed when the value of the advantageous section game number counter becomes "1500" or more (that is, when games during the advantageous section are played 1500 times in a row). The advantageous section game counter starts counting the number of games when the advantageous section (including the performance section) starts, and when the advantageous section ends (including the end due to the activation of the limit process). It is cleared (initialized) after the counting ends. Further, the advantageous section game number counter counts both when the number of bets is two and three. Further, the advantageous section game number counter performs counting also in the 2BB state and the 3BB state.

When the normal limit processing (number of games) is executed (operated), the advantageous section is forcibly ended and the non-advantageous section is completed, regardless of whether it is during the production section or the increase section (pseudo bonus). to be transferred to In addition, at this time, information regarding advantageous sections (for example, information for controlling the effect section and increase section, information regarding the current mode, information regarding the playing period of pseudo bonuses, information regarding the number of ceiling games and whether there is ceiling reduction) information, various information obtained during the advantageous section such as the value of the 1G continuous stock counter, and various information necessary to control the advantageous section) are all cleared (initialized).

The normal limit process (number of payouts) is executed when the value of the advantageous section payout number counter becomes "2401" or more (that is, when the number of medals paid out during the advantageous section exceeds 2400). In addition, the advantageous section payout number counter starts counting the number of medals (here, for example, "net increase (difference number)") that has been paid out since the start of the advantageous section (including the performance section). When the section ends (including the end due to activation of the limit process), the counting is ended and cleared (initialized). Further, the advantageous section payout number counter performs counting whether the number of bets is two or three. Further, the advantageous section payout number counter performs counting also in the 2BB state and the 3BB state. In addition, the advantageous section payout number counter will count as appropriate according to the actual number of payouts (for example, "-2 pieces" or "-3 pieces", etc.) when a "miss" or "missed" occurs during the advantageous section, for example. The value is subtracted. Therefore, if the number of medals does not increase but decreases after the start of the advantageous section, it may become a negative value (or, if it becomes a negative value, it will always remain ``0''). ). That is, the advantageous section payout number counter is capable of counting the number of medals paid out during the advantageous section from the lowest point to the defined maximum point (difference in number of medals: 2400).

When the normal limit process (number of payouts) is executed (activated), the advantageous section is forcibly ended, regardless of whether it is during the production section or the increase section (pseudo bonus), and the non-advantageous section to be transferred to Also, at this time, all information regarding the advantageous sections mentioned above is also cleared (initialized).

The special limit process (number of games) is executed when the value of the control game number counter becomes "1445" or more (that is, when games in the advantageous section are played 1445 times in a row). The control game number counter starts counting the number of games when the advantageous section (including the performance section) starts, and when the advantageous section ends (including the end due to the activation of the limit process). It is cleared (initialized) after the counting ends. Further, the control game number counter counts when the number of bets is three, and does not count when the number of bets is two. Further, the control game number counter performs counting when the game is in the non-bonus state, and does not perform counting when the game is in the 2BB state and the 3BB state. However, the control game number counter may have the same configuration as the advantageous section game number counter.

When the special limit processing (number of games) is executed (activated), if the pseudo bonus is in progress (that is, during the increase period), the pseudo bonus will be activated without forcibly ending the pseudo bonus in the middle. When the advantageous section is completed, the advantageous section is forcibly terminated and shifted to the non-advantageous section. Also, at this time, all information regarding the advantageous sections mentioned above is also cleared (initialized).

On the other hand, if the pseudo bonus is not in progress (that is, if it is in the performance section), first, the process is forcibly shifted to the pseudo bonus. That is, even if the pseudo bonus transfer lottery is not won, the transfer to the pseudo bonus is made by executing this special limit process (number of games). Then, when the transferred pseudo-bonus ends, the advantageous section is forcibly ended accordingly, and the transition is made to a non-advantageous section. Also, at this time, all information regarding the advantageous sections mentioned above is also cleared (initialized).

Here, the value of the advantageous section game number counter in which the normal limit processing (number of games) is executed (operates) is "1500", whereas the special limit processing (number of games) is executed (operates). Focusing on the fact that the value of the control game number counter is "1445", in the first gaming machine, the maximum number of games (continuable period) during the pseudo bonus is "55 games" (Fig. 5), this difference takes into account the playable period during the pseudo bonus.

In other words, the normal limit processing (number of games) is executed when a predetermined regulation period has been played in an advantageous area in order to prevent the gambling nature of the game from becoming excessively high. However, for example, if this normal limit processing (number of games) is executed immediately after the pseudo bonus starts or during it, the player will feel a sense of distrust or loss, which will reduce the interest in the game. There are cases. Therefore, in the first gaming machine, special limit processing (number of games) is performed on a game that is the continuable period (55 games) per increase period before the game on which normal limit processing (number of games) is performed. By executing this, it is possible to prevent the player from feeling a sense of distrust or loss due to the pseudo bonus being terminated midway.

Note that from this point of view, the timing at which the special limit process (number of games) is executed (operated) is not limited to the above-mentioned timing. For example, the special limit process (number of games) is executed before the game where the normal limit process (number of games) is executed by the continuation period (55 games x 2 sets = 110 games) per 2 increase periods. It is also possible to do so. Also, for example, in order to give a slight grace period, the limit processing (number of games) is normally executed before the continuation period (55 games) + grace period (2 games) per increase period. A special limit process (number of games) may be executed in the game. Also, for example, in the case of specifications such as going through a precursor state before moving to a pseudo bonus, and the maximum number of games in this precursor state is "4 games", the normal limit process (number of games) is executed. The special limit process (number of games) may be executed in a game that is a continuable period (55 games) + maximum precursor period (4 games) per increase period before the game that is played. In other words, the timing at which the special limit processing (number of games) is executed (activated) may be any timing before the timing at which the normal limit processing (number of games) is executed; It is assumed that settings can be made as appropriate depending on the game specifications, etc.

The special limit process (number of payouts) is executed when the value of the control payout number counter becomes "2126" or more (that is, when the number of medals paid out during the advantageous section exceeds 2125). In addition, the control payout number counter starts counting the number of medals (here, for example, "net increase number (difference number)") from the time when the advantageous section (including the performance section) starts, and When the section ends (including the end due to activation of the limit process), the counting is ended and cleared (initialized). Further, the control payout number counter performs counting when the number of bets is three, and does not perform the counting when the number of bets is two. Further, the control payout number counter performs counting when in a non-bonus state, and does not perform counting when in a 2BB state and a 3BB state.

In addition, when a "miss" occurs in the advantageous section, the control payout number counter is decremented by an appropriate value according to the actual number of payouts (for example, "-3 coins", etc.). However, the control payout number counter does not cause a "missing medal" (or a difference) when a "missing medal" occurs during an advantageous section (at least when a difference occurs from the maximum number of medals paid out). The number of medals paid out is counted. Specifically, for example, in a game where you bet 3 medals and win "Push Order Bell A", if the batting order is appropriate, the number of medals paid out (maximum value) is "8" (the difference number is " On the other hand, if the batting order is not appropriate, if the pressing position is appropriate, the number of medals paid out will be ``1'' (the difference in number of medals is ``-2''), and if the pressing position is not appropriate. If a medal is missed, the number of medals paid out becomes "0" (the difference number is "-3"), but the control payout number counter shows the difference number "-3" in any case in the game. +5 pieces” are counted.

In addition, for example, when the value of the advantageous section payout number counter becomes larger than the value of the control payout number counter due to activation of the 2BB state or 3BB state, the value of the control payout number counter becomes It is corrected to the value of the section payout number counter. Note that the control payout number counter may have the same configuration as the advantageous section payout number counter.

When the special limit process (number of payouts) is executed (activated), if the pseudo bonus is in progress (that is, if it is in the increase period), the pseudo bonus will be released without forcibly ending the pseudo bonus in the middle. When the advantageous section is completed, the advantageous section is forcibly terminated and shifted to the non-advantageous section. Also, at this time, all information regarding the advantageous sections mentioned above is also cleared (initialized).

On the other hand, if the pseudo bonus is not in progress (that is, if it is in the performance section), first, the process is forcibly shifted to the pseudo bonus. That is, even if the pseudo-bonus transfer lottery is not won, the transfer to the pseudo-bonus is made by executing this special limit process (number of payouts). Then, when the transferred pseudo-bonus ends, the advantageous section is forcibly ended accordingly, and the transition is made to a non-advantageous section. Also, at this time, all information regarding the advantageous sections mentioned above is also cleared (initialized).

Here, the value of the advantageous section payout number counter where normal limit processing (number of payouts) is executed (operates) is "2401", whereas special limit processing (number of payouts) is executed (operates) Focusing on the fact that the value of the control game number counter is "2126", in the first gaming machine, the maximum number of coins acquired in the pseudo bonus (amount of game value that can be awarded) is "275 coins". (See FIG. 5), this difference takes into consideration the amount of gaming value that can be awarded in the pseudo bonus.

In other words, the normal limit processing (number of payouts) is executed when a predetermined regulated gaming value amount of gaming value is awarded in an advantageous area in order to prevent the gambling nature of the game from becoming excessively high. However, for example, if this normal limit processing (number of payouts) is executed immediately after or during the start of a pseudo bonus, the player will feel distrust and loss, and the interest in the game will decrease. There are cases where this happens. Therefore, in the first gaming machine, a gaming value amount that is less than the gaming value amount for which limit processing (number of payouts) is normally executed is given by the amount of gaming value that can be given per increase section (275 coins). By occasionally executing special limit processing (number of payouts), it is possible to prevent the player from feeling distrustful or lost due to the pseudo-bonus ending prematurely.

From this point of view, the timing at which the special limit process (number of payouts) is executed (operated) is not limited to the above-mentioned timing. For example, when a gaming value amount that is less than the gaming value amount for which the normal limit processing (number of payouts) is executed is awarded by the amount of gaming value that can be awarded per two increase periods (275 coins x 2 sets = 550 coins). A special limit process (number of payouts) may be executed. For example, in order to provide a slight grace period, the amount of gaming value that can be awarded per increase period (275 coins) + grace period is equivalent to the amount of gaming value that can be granted per increase period (275 coins) + the amount of gaming value for which limit processing (number of payouts) is normally executed. A special limit process (number of games) may be executed when a game value amount less than the game value amount (8 pieces) is awarded. In other words, the special limit process (number of payouts) may be executed (activated) at any timing before the normal limit process (number of payouts). It is assumed that settings can be made as appropriate depending on the game specifications, etc.

For semi-limit processing (number of games), add "1" to the value of the control game counter (if you win the ceiling shortening lottery and it becomes "with ceiling shortening"), add "1" to the value of the 1G continuous counter. ) is multiplied by "55" (that is, the period during which the pseudo bonus can be continued), and is executed when the addition result becomes "1390" or more. For example, if the value of the 1G continuous counter is "1" and "with ceiling shortening", the latter value is "55 x 2 = 110", so the value of the control game number counter is "1280". ”, the semi-limit process (number of games) will be executed (activated).

For semi-limit processing (number of payouts), add "1" to the value of the control payout number counter and the value of the 1G continuous counter (if you win the ceiling shortening lottery and it is "with ceiling shortening"), add "1". ) is multiplied by "275" (that is, the amount of game value that can be given as a pseudo bonus), and is executed when the addition result becomes "1851" or more. For example, if the value of the 1G continuous counter is "1" and it is "with ceiling shortening", the latter value is "275 x 2 = 550", so the value of the control payout number counter is "1301". ”, the semi-limit process (number of payouts) will be executed (activated). Note that semi-limit processing (number of games) and semi-limit processing (number of payouts) both have the same restrictions, so after one operating condition is established and activated, the other operating condition will be applied. Even if this holds true, there is no need for it to operate redundantly.

When the semi-limit processing (number of games) or the preparation limit processing (number of payouts) is executed (activated), the above-mentioned 1G continuous lottery and ceiling shortening lottery are executed during the pseudo bonus in a series of subsequent advantageous sections. It will no longer be done. That is, the extension of the gaming period in the increased section is suppressed. Note that the method for suppressing the extension of the gaming period in the increased section is not limited to this. For example, in the above-mentioned 1G consecutive lottery, the probability of winning the 1G consecutive lottery may be set to be lower than usual, and in the above-mentioned ceiling shortening lottery, the winning probability of the ceiling shortening may be set to be lower than usual. . That is, although the above-mentioned 1G consecutive lottery and ceiling shortening lottery are executed, it may be made so that it is difficult to win these lots. Further, for example, in the production section after the execution of the quasi-limit process (number of games), the lottery value that becomes a winning prize in the pseudo-bonus transfer lottery may be lowered to make it difficult to transfer to the pseudo-bonus. Alternatively, in the mode transition lottery, the lottery value at which a mode transition advantageous to the player is determined may be lowered to make it difficult for pseudo bonuses to be won consecutively.

In addition, when the semi-limit processing (number of games) or the semi-limit processing (number of payouts) is executed (activated), in the subsequent series of advantageous sections, during the production section, the "determined hand" (( A special process is performed when a) is won. Hereinafter, this special processing will be explained using as an example a case where the "confirmed combination" is "F_confirmed cherry" (hereinafter sometimes simply referred to as "confirmed cherry").

When neither the quasi-limit processing (number of games) nor the quasi-limit processing (number of payouts) is in operation, if a "certain cherry" is won during the performance period (may be during the increase period), a pseudo-bonus transition lottery occurs. ``Winning (next game)'' is determined (see (c) in FIG. 7). In addition, in the first gaming machine, the "cherry" symbol on the left reel 3L is a highly anticipated symbol for the player, so in games where information about stop operations is not reported, the player The general procedure is to perform the stop operation by making one stop and aiming at the "Cherry" symbol (as a guideline, aim at the "BAR" symbol). Therefore, when a game is played according to the general procedure, when a "determined cherry" is won, the "cherry" symbol is first stopped at the lower row of the left reel 3L at the first left stop. In addition, when neither the semi-limit processing (number of games) nor the semi-limit processing (number of payouts) is activated, if a "confirmed cherry" is won, the left first stop ("batting order 1" and "batting order 2" ”) may be made. Further, "winning (next game)" is not limited to a pseudo bonus starting from the next game, but may also mean a pseudo bonus starting from the next game or later.

Here, a skilled player also aims at the "BAR" symbol on the middle reel 3C and right reel 3R and stops, in order to further determine whether it is a "weak cherry" or a "certain cherry". Perform operations. As a result, the "BAR" symbols line up in the middle of each reel, and it can be recognized that the "confirmed cherry" has been won (for example, see "REP42" in FIG. 11). On the other hand, an unskilled player, for example, may not or may not be able to perform the stop operation while aiming at the "BAR" symbol on the middle reel 3C and right reel 3R, and the stop display may appear to be a "weak check". It may not be possible to determine whether it is a "determined cherry" (for example, see "REP28" in FIG. 11).

In addition, in the first gaming machine, when neither the semi-limit processing (number of games) nor the semi-limit processing (number of payouts) is in operation, when a "confirmed cherry" is won, the "confirmed cherry reply" is not activated. When a combination of symbols is displayed, a special winning sound is output. Also, if you win a "Confirmed Cherry" and the "Confirmed Cherry Lip" symbol combination is not displayed, but the "Cherry Lip" symbol combination is displayed, a special winning sound will also be played. It is now output. Note that the special winning sound may be output with a probability of 100%, or with a predetermined probability (for example, a probability of 50%).

In any case, when neither the semi-limit processing (number of games) nor the semi-limit processing (number of payouts) is in operation, if you win a "certain cherry", at the start of the next game, "red 7" ” will be performed and it will be announced that the pseudo bonus will start, and the pseudo bonus will start.

On the other hand, if a "guaranteed cherry" is won during the production period (or may be during the increase period) after either the semi-limit processing (number of games) or the semi-limit processing (number of payouts) is activated, a pseudo bonus will be transferred. Although the "win (next game)" is once determined in the lottery (see (c) in FIG. 7), this determination result is rewritten to "win (the current game)" by executing the special process. Then, at the start of the current game, it is announced that a "red 7" effect will be performed and a pseudo bonus will be started, and the pseudo bonus will be started.

At this time, in this game, the stop operation is performed to display the "Middle Rip" symbol combination without displaying the "Confirmed Cherry Rip" symbol combination (including the "Cherry Rip" symbol combination). Information notification (special notification) is performed. For example, in the first gaming machine, a special notification is given to the effect that the first right stop ("batting order 5" and "batting order 6") should be made (see FIG. 15). As a result, when neither the semi-limit processing (number of games) nor the semi-limit processing (number of payouts) is in operation, the flow of the game was changed from displaying "confirmed cherry reply" to starting a pseudo bonus from the next game. After either the semi-limit processing (number of games) or the semi-limit processing (number of payouts) is activated, a pseudo bonus starts from the current game → a stop operation is performed according to the special notification, and a game called "middle rep" is displayed. The flow will be changed to Note that the special notification may be performed under the control of the main (main control board 71) side, and from the viewpoint that the player will not be disadvantaged even though it will shift to a pseudo bonus as a result. The control may be performed only on the sub (sub control board 72) side.

In addition, if you win a "confirmed cherry" after either the semi-limit process (number of games) or the semi-limit process (number of payouts) is activated, and even though a special notification has been made, the "confirmed cherry" When the symbol combination “Cherry Rip” is displayed, no special winning sound is output.

Furthermore, in the first gaming machine, when "F_Replay A" or "F_Replay B" is determined as the internal winning combination, basically the procedure for the stop operation is not notified. For this reason, assuming that the stop operation procedure is announced and the "Middle Reply" is displayed only when the above-mentioned special notification is performed, if such a situation occurs, one of the The player will clearly recognize that the semi-limit process has been activated, which may reduce the interest in the game. Therefore, during the advantageous section, regardless of whether or not any semi-limit process is activated (or it may be after the activation of any quasi-limit process), "F_Replay A" or When "F_Replay B" is determined as the internal winning combination, a notification similar to the special notification may be made with a predetermined probability. In this way, it is possible to prevent the player from feeling unnatural about the special notification. Further, when "F_Replay A" or "F_Replay B" is determined as the internal winning combination, the same notification as the special notification may be made when the pseudo bonus transfer lottery is won. In addition, in this case, in the pseudo bonus transfer lottery when "F_Replay A" or "F_Replay B" is determined as the internal winning combination, even if it is configured such that "Win (current game)" can be determined with a predetermined probability. good.

Up to this point, we have explained using the example of monitoring the gaming period in the advantageous section using the "number of games" and "number of payouts" in order to activate the normal limit processing, special limit processing, and semi-limit processing. The conditions under which each limit process is executed are not limited to those described above, and may be changed as appropriate. For example, when each limit process is executed, the value of the advantageous section game number counter, the value of the advantageous section payout number counter, the value of the control game number counter, the value of the control payout number counter, and the value of the 1G continuous counter. The presence or absence of ceiling shortening (that is, the variable for activating the quasi-limit process), etc. can be changed as appropriate according to game specifications, market trends, and the like.

Further, the method for monitoring the gaming period of the advantageous section is not limited to the above-mentioned method. For example, if you use the "Navi count" to monitor the gaming period in the advantageous section, you can use normal limit processing (Navi count), special limit processing (Navi count), or semi-limit processing (Navi count) in the same way as above. (number of times) can also be executed. In other words, any element (parameter) whose value can be counted can be used to monitor the gaming period in the advantageous section, and the value at which limit processing is normally performed for the adopted element. By defining a value for which special limit processing is executed, and a value for which quasi-limit processing is executed, each limit process can be executed in the same manner as described above.

As described above, in the first gaming machine, the advantageous state (for example, pseudo bonus) and the specific state (for example, performance section) are controlled as a series of advantageous sections, and the gaming period in this series of advantageous sections is controlled for a predetermined period (for example, , the value of the number of advantageous section games counter is "1500" or more), or the amount of gaming value awarded in this series of advantageous sections reaches a predetermined amount (for example, the value of the number of advantageous section payout counters is "2401" or more). ), this series of advantageous sections is forcibly terminated, but if the gaming period in this series of advantageous sections is shorter than the predetermined period (for example, the value of the control game number counter is "1445") or above), or when the amount of gaming value awarded in this series of advantageous sections becomes a specific amount less than the predetermined amount (for example, the value of the control payout number counter is "2126" or more), If the vehicle is in an advantageous state, the series of advantageous sections are terminated when the vehicle transitions to a specific state.

That is, in the first gaming machine, the series of advantageous sections are not forcibly terminated in the middle of an advantageous state, and the series of advantageous sections are ended within a certain period of time in a natural flow as the advantageous condition ends. It is possible to do so. This makes it possible to prevent players from feeling a sense of distrust or loss while also preventing the gambling nature from becoming excessively high, making it possible to consider the feelings of players. It is said that

Further, in the first gaming machine, the advantageous state (for example, pseudo bonus) and the specific state (for example, performance section) are controlled as a series of advantageous sections, and the gaming period in this series of advantageous sections is maintained for a predetermined period (for example, advantageous section). When the value of the section game number counter is "1500" or more), or when the amount of gaming value awarded in this series of advantageous sections reaches a predetermined amount (for example, the value of the advantageous section payout number counter is "2401" or more) When this happens, this series of advantageous sections is forcibly ended, but if the gaming period in this series of advantageous sections is shorter than the predetermined period (for example, the value of the control game number counter is "1445" or more) , or when the amount of gaming value awarded in this series of advantageous sections becomes a specific amount smaller than the predetermined amount (for example, the value of the control payout number counter is "2126" or more), an advantageous state If not, the system shifts to an advantageous state, and when the shifted advantageous state ends and shifts to a specific state, the series of advantageous sections ends.

That is, in the first gaming machine, the series of advantageous sections are not forcibly terminated in the middle of an advantageous state, and the series of advantageous sections are ended within a certain period of time in a natural flow as the advantageous condition ends. It is possible to do so. Moreover, when ending a series of advantageous sections in this way, if the condition is not advantageous, it is changed to an advantageous condition and then terminated. This makes it possible to prevent players from feeling a sense of distrust or loss while also preventing the gambling nature from becoming excessively high, making it possible to consider the feelings of players. It is said that

Further, in the first gaming machine, the specific period or the specific amount is set in consideration of the period during which an advantageous state can continue (for example, "55 games") or the amount of game value that can be awarded (for example, "275 coins"). Therefore, while giving due consideration to the emotions of the players, it is possible to prevent the amount of gaming value given to the players from being extremely restricted.

In addition, in the first gaming machine, the advantageous state may be extended by the granted rights (for example, "1G continuous stock" and "ceiling shortening"), but the gaming period in the series of advantageous sections is limited to a specific period. When the special period is shorter and is set according to the number of rights granted (for example, when the value of the control game number counter reaches a value at which semi-limit processing (number of games) is executed), Or, when the amount of gaming value awarded in a series of advantageous sections is less than a specific amount and becomes a special amount set according to the number of rights granted (for example, when the value of the control payout counter is at the semi-limit) When the processing (number of payouts) reaches a value that is executed, the granting of rights is suppressed in the subsequent series of advantageous sections. As a result, for example, the player may be granted more rights than he or she can consume, and in such a situation, a series of advantageous sections will be forcibly terminated, causing the player to feel a sense of distrust or loss. Since this can be prevented, it is possible to prevent the gambling nature from becoming excessively high while also considering the emotions of the players.

In addition, in the first gaming machine, when counting the above-mentioned "specific amount" and "special amount," it is important to note that, for example, when the above-mentioned "specific amount" and "special amount" are Even if there is a difference between the amount of gaming value that was originally awarded and the amount of gaming value that was actually awarded, the calculation is based on the amount of gaming value that was originally supposed to be awarded, without taking this difference into account. It is about to be done. As a result, the series of advantageous sections may be extended unnecessarily due to the actions of such players, and unfairness may arise between players who have committed such actions and players who have not. Since it is possible to prevent players from putting the game away, it is possible to prevent the gambling nature from becoming excessively high while also considering the emotions of the players.

In addition, in the first gaming machine, a player wins a fixed combination (for example, a "fixed cherry") that is guaranteed to transition to an advantageous state in a state where the granting of rights is suppressed (for example, a state after semi-limit processing is activated). When this happens, a special notification is made to prevent the display of special symbol combinations (for example, "confirmed cherry rip") that can clearly recognize the winning of this confirmed combination. As a result, it is possible to prevent the player from feeling, for example, that the winning of the confirmed winning combination was a useless winning. In other words, in a state where the granting of rights is suppressed, by preventing the player from clearly recognizing the trigger when an advantageous state has started, it is possible to suppress the gambling nature from becoming excessively high, while also making the game more enjoyable. This makes it possible to consider people's feelings as well. Note that any effect execution means may be used to perform the special notification.

Further, in the first gaming machine, when a special notification is given, the advantageous state that was originally supposed to start from the next game starts from the current game. This allows the player to perform the stop operation in accordance with the special notification in a natural flow, thereby preventing the player from feeling uncomfortable even when such a special notification is issued. can.

In addition, in the first gaming machine, when the granting of rights is not suppressed and a combination of special symbols is displayed due to a winning combination, a special notification (for example, output of a special winning sound) is performed. On the other hand, when the granting of rights is suppressed and a combination of special symbols is displayed in a winning combination, it is not possible to make a special notification. As a result, it is possible to prevent the player from feeling, for example, that the winning of the confirmed winning combination was a useless winning. In other words, in a state where the granting of rights is suppressed, by preventing the player from clearly recognizing the trigger when an advantageous state has started, it is possible to suppress the gambling nature from becoming excessively high, while also making the game more enjoyable. This makes it possible to consider people's feelings as well. Note that any performance execution means may be used to make the special notification.

In addition, the first gaming machine determines whether or not to make a special notification depending on whether or not a confirmed winning combination has been won, whether or not a combination of special symbols has been displayed, and whether or not a special notification has been made. I'm trying to decide. Thereby, the situation in which special notification is performed can be managed more appropriately.

In addition, in the first gaming machine, the advantageous section game number counter and the advantageous section payout number counter perform counting regardless of the amount of betted game value, and as a result, not only in the 3-card bet state but also in the 2-card bet state, This allows normal limit processing (number of games) and normal limit processing (number of payouts) to be executed.

Further, in the first gaming machine, the control game number counter and the control payout number counter perform counting in the 3-card bet state, but do not perform counting in the 2-card bet state. Therefore, in the 3-card bet state, special limit processing (number of games) and special limit processing (number of payouts) can be executed, but in the 2-card bet state, special limit processing (number of games) and special limit processing (number of payouts) can be executed. Processing (number of payouts) is not allowed to be executed. Therefore, in a two-card bet state, the series of advantageous sections may be forcibly terminated even during a pseudo bonus by executing the normal limit process (number of games) or the normal limit process (number of payouts).

In addition, in the first gaming machine, for example, the winning probability of the small winning combination and the number of medals paid out are different between the 3-piece bet state and the 2-piece bet state (see FIGS. 10 to 15), and the 3-piece bet state is different. The player is at a disadvantage when playing a game with two bets than when playing a game with . However, the method in which the player is disadvantaged when playing a game with two bets is not limited to this. For example, if a game is played with two bets during a pseudo bonus, the procedure for stopping the game may not be notified, thereby putting the player at a disadvantage.

In this way, in the first gaming machine, when a game is played with a first amount of gaming value (for example, "3 coins") being bet, a series of advantageous sections are forced in the middle of an advantageous state. This makes it possible to end a series of advantageous sections within a certain period of time in a natural flow that accompanies the end of an advantageous state. This makes it possible to prevent players from feeling a sense of distrust or loss while also preventing the gambling nature from becoming excessively high, making it possible to consider the feelings of players. It is said that On the other hand, if a second amount of gaming value (for example, "2 coins") is bet and a game is played, a series of advantageous sections may be forcibly terminated in the middle of an advantageous state. This makes it possible for the player to realize that he or she did not play the game using the intended gaming method, thereby encouraging the player to play the game using the intended gaming method.

Furthermore, in a series of advantageous sections, it is more disadvantageous for the player when the second amount of gaming value is bet and the game is played than when the first amount of gaming value is bet and the game is played. Therefore, by making it possible to call attention to this, it is possible to encourage the player to play the game in a more advantageous situation, and to prevent the player from playing the game in a way that is not intended by the player. It is possible to prevent the interest in the game from decreasing due to this.

[5-5. Storage area configuration of first gaming machine]
Next, the storage area configuration of the first gaming machine will be described with reference to FIGS. 17 to 22. FIG. 17 is a diagram showing an example of the winning flag storage area, the winning activation flag storage area, and the symbol code storage area of the first gaming machine. Further, FIG. 18 is a diagram showing an example of a carryover combination storage area of the first gaming machine. Further, FIG. 19 is a diagram showing an example of a gaming state flag storage area of the first gaming machine. Further, FIG. 20 is a diagram showing an example of a mode flag storage area of the first gaming machine. Further, FIG. 21 is a diagram showing an example of the operation stop button storage area of the first gaming machine. Further, FIG. 22 is a diagram showing an example of a pressing order storage area of the first gaming machine.

(Winning flag storage area, winning activation flag storage area, and symbol code storage area)
First, with reference to FIG. 17, the configurations of the winning flag storage area (internal winning combination storage area), winning activation flag storage area (display combination storage area), and symbol code storage area will be described. In addition, in the first gaming machine, the winning flag storage area, the winning activation flag storage area, and the symbol code storage area have the same data configuration.

Each of the storage areas described above is composed of storage areas 1 to 26, each represented by 1 byte of data. Although the data stored in each storage area is only 1-byte data in the "Data" column in FIG. 17, for convenience of explanation, the symbol combinations associated with the bits in each storage area are shown in FIG. The "combinations" shown (in FIG. 17, the symbols on reel 3L, the symbols on reel 3C, and the symbols on reel 3R are described in this order) and their contents (see FIGS. 11 to 14) are also described.

The data stored in the winning flag storage area allows the main CPU 101 to identify the type of symbol combination that corresponds to the internal winning combination (that is, the type of symbol combination that is permitted to be displayed in the current game). It is used to For example, if 2BB is won in the current game (if carried over), "1" is stored in bit 0 of storage area 1.

The data stored in the winning activation flag storage area allows the main CPU 101 to identify the type of symbol combination corresponding to the displayed combination (that is, the type of symbol combination displayed on the active line in the current game). used for For example, if a combination of symbols related to 2BB is displayed on the active line in the current game, "1" is stored in bit 0 of storage area 1.

The data stored in the symbol code storage area allows the main CPU 101 to identify the types of symbol combinations that can still be displayed on the active line in the current game while at least one of the reels is rotating. used for For example, in this game, when at least one of the reels is rotating, if the combination of symbols related to 2BB can be displayed on the active line, "1" is set in bit 0 of storage area 1. is stored.

(Carryover win storage area)
Next, with reference to FIG. 18, the configuration of the carryover winning combination storage area will be explained. The carryover combination storage area is composed of a storage area represented by 1 byte of data.

As a result of the internal lottery process, when a bonus combination of "F_2BB" (2BB) or "F_3BB" (3BB) is determined as an internal winning combination, these bonus combinations are stored in the carryover combination storage area as a carryover combination ( "1" is stored in the corresponding bit). The carryover combination stored in the carryover combination storage area is held without being cleared until the corresponding combination of symbols is displayed on the active line. In addition, while the carryover winnings are stored in the carryover winnings storage area, the carryover winnings (bonus winnings) are stored in the winning flag storage area in addition to the internal winnings determined by the internal lottery process (minor winnings/replay winnings). be done.

(Game status flag storage area)
Next, with reference to FIG. 19, the configuration of the gaming state flag storage area will be described. The gaming state flag storage area is composed of a storage area represented by 1 byte of data. For example, when the current gaming state is the 2BB state, "1" is stored in bit 0 of the storage area.

Note that in the first gaming machine, since the RT state is not provided, the gaming state flag storage area shown in FIG. 19 is not provided with an area indicating the type of RT state. If so, "1" is stored in the bit of the storage area corresponding to the current RT state. Note that in the first gaming machine, data indicating the type of gaming state (mode) during the advantageous section is stored separately in a mode flag storage area, which will be described later. You can also. Further, the same applies to the game sections of the non-advantageous section and the advantageous section. It is possible to provide an advantageous section flag storage area (not shown) for management, or it is also possible to store and manage the game status flag in this gaming state flag storage area. The same applies to gaming states such as the AT state and the ART state. It is possible to provide an AT state (ART state) flag storage area (not shown) for management, or it is also possible to store and manage the game state flag in this gaming state flag storage area.

(mode flag storage area)
Next, the configuration of the mode flag storage area will be described with reference to FIG. 20. The mode flag storage area is composed of storage area 1 and storage area 2, each represented by 1 byte of data. For example, if the current mode is the start mode, "1" is stored in bit 0 of storage area 1. Further, for example, if the current mode is Heaven A mode, "1" is stored in bit 0 of storage area 2. Note that in the first gaming machine, the pseudo-bonus state is also managed as one of the modes.

(Operation stop button storage area)
Next, the configuration of the operation stop button storage area will be described with reference to FIG. 21. The operation stop button storage area is composed of a storage area represented by 1 byte of data. Furthermore, bits 0 to 2 of the operation stop button storage area store data indicating the type of stop button that has already been operated (type of stopped reel), and bits 4 to 6 store data indicating the type of stop button that has already been operated. Stores data indicating the type (type of reel being rotated).

For example, if the stop button 8L is the currently pressed stop button, that is, the operation stop button, "1" is stored in bit 0 of the operation stop button storage area. Further, for example, if the stop button 8L is a stop button that has not been pressed yet, that is, it is a valid stop button, "1" is stored in bit 4. The main CPU 101 identifies the stop button that has been pressed this time and the stop button that has not been pressed yet, based on the data stored in the operation stop button storage area.

(Press order storage area)
Next, the configuration of the press order storage area will be described with reference to FIG. 22. The press order storage area is composed of a storage area represented by 1 byte of data. Note that the pressing order indicates the order in which the stop buttons were pressed, that is, the pressing order (batting order).

For example, when all the reels are rotating, "1" is stored in bits 0 to 5 of the press order storage area. Next, when the stop button 8L is pressed (because it is the "left" first stop), "1" remains stored in bits 0 and 1, but "0" is stored in bits 2 to 5. will be stored. Next, when the stop button 8C is pressed (because it is the "left" first stop and the "middle" second stop), "1" remains stored in bit 0, but "1" remains stored in bit 1. "0" is now stored. The main CPU 101 identifies the pressing order for the current game based on the data stored in the pressing order storage area.

[6. Processing by main control circuit]
Next, the contents of various processes executed by the main CPU 101 of the main control circuit 100 using each program will be explained with reference to FIGS. 23 to 32. In addition, in the description of the various processes shown below, a specific example of the processing content may be explained using the specifications of the first gaming machine, but the processing content of the various processes shown below is limited to this. It's not a thing.

[6-1. Main processing]
First, with reference to FIG. 23, the main processing (main operation processing) executed by the main CPU 101 of the main control circuit 100 will be described. Note that FIG. 23 is a flowchart showing an example of the procedure of the main processing. FIG. 23 also shows power-on processing that is executed prior to the start of the main processing.

First, when power is supplied to the pachi-slot machine 1 (when the power is turned on), the main CPU 101 performs a power-on process (S1). In this process, various processes necessary when the power is turned on are performed. Note that details of the power-on processing will be described later.

Next, the main CPU 101 performs initialization processing at the end of one game (S2). In this process, the data in the designated storage area in the main RAM 103 is cleared. Note that the designated storage area here is, for example, a storage area such as a winning flag storage area or a winning activation flag storage area where data needs to be erased for each unit game (game).

Next, the main CPU 101 performs medal acceptance/start check processing (S3). In this process, for example, the input states of the medal sensor 31S, bet switch 6S, start switch 7S, etc. are checked, and various processes necessary at the start of the game are performed. The details of the medal reception/start check process will be described later.

Next, the main CPU 101 performs random value acquisition processing (S4). In this process, random numbers for internal lottery (for example, in the range of 0 to 65535) and random numbers for performance (other random numbers for lottery) used in various kinds of lottery related to gameplay (for example, in the range of 0 to 65,535, or 0 to 255 range), etc., and the various extracted random numbers are stored in a random number storage area (not shown) provided in the main RAM 103. Note that the manner in which various random numbers are obtained is not limited to the above. The required number of random values can be obtained as appropriate from each predetermined numerical range (for example, the range 0 to 65535, the range 0 to 32767, the range 0 to 255, or the range 0 to 127, etc.). .

Next, the main CPU 101 performs an internal lottery process (S5). In this process, various processes necessary for determining an internal winning combination are performed based on an internal lottery table and random numbers for internal lottery depending on the current gaming state and the like. Note that details of the internal lottery process will be described later.

Next, the main CPU 101 performs game start state control processing (S6). In this process, for various game states, when a game starts, if a transition condition is satisfied (for example, based on a determined internal winning combination, etc.), the game state is transitioned according to the established transition condition. , or perform various processes necessary to manage the gaming period of the current gaming state. The details of the state control process at the start of the game will be described later.

Next, the main CPU 101 performs start command generation and storage processing (S7). In this process, data of a start command to be sent to the sub-control circuit 200 is generated, and the generated data is stored in a communication data storage area (not shown) provided in the main RAM 103. Note that the data stored in the communication data storage area is transmitted from the main control circuit 100 to the sub control circuit 200 in a communication data transmission process (see S204 in FIG. 32), which will be described later. Furthermore, the methods of generating, storing, and transmitting data for other commands are basically the same.

Subsequently, the main CPU 101 performs main-side performance control processing at the start of the game (S8). In this process, when starting a game and performing various effects under the control of the main control circuit 100 side (main side), various processes necessary for performing the effects are performed. For example, when a lock effect is performed at the start of a game, execution of the lock effect is controlled. Furthermore, if this includes a pseudo game, the progress of the pseudo game (or notification regarding the pseudo game) is controlled. Further, for example, when the instruction monitor is in the AT state and informs information of a stop operation, the manner of the notification is controlled. Further, although the details are omitted, when a lock effect is performed, a lock command generation and storage process is performed in this process.

Next, the main CPU 101 performs reel stop initial setting processing (S9). In this process, various information necessary for stop control, such as the type of stop table used in the current game and the type of attraction priority table, is set based on the internal winning combination, the game state, etc.

Next, the main CPU 101 performs reel rotation start processing (S10). This process requests the start of rotation of all reels. Then, when the start of rotation of all the reels is requested, the driving of each stepping motor 51L, 51C, 51R is controlled by the reel control process (see S203 in FIG. 32) described later, and the driving of each stepping motor 51L, 3C, 3R is controlled. Rotation begins. Each reel that has started rotating is accelerated and controlled until its rotational speed reaches a constant speed, and then the constant speed is maintained. Further, although the details are omitted, in this process, a reel rotation start command generation and storage process is performed.

Next, the main CPU 101 performs an attraction priority order storage process (S11). In this process, the pull-in priority is determined for each symbol (symbol position) on the spinning reels (all reels in this case) by referring to the set internal winning combination and the set pull-in priority table. The data shown is acquired and stored in an attraction priority order data storage area (not shown). Although not shown, a symbol code storage process, which will be described later, is performed prior to this process.

Next, the main CPU 101 performs reel stop control processing (S12). In this process, the rotation of the corresponding reel is stopped based on the determined internal winning combination (or information related to various stop controls set accordingly) and the stop operation mode of each stop button 8L, 8C, and 8R. Perform various processing necessary for this purpose. Note that details of the reel stop control process will be described later.

Subsequently, the main CPU 101 performs a winning operation determination process (S13). In this process, it is determined whether the combination of symbols displayed on the active line is any combination of symbols defined in the symbol combination table. For example, it is determined whether there is a bit in which "1" is stored in the winning operation flag storage area. Further, although the details are omitted, in this process, a winning activation command generation and storage process is performed.

Next, the main CPU 101 performs medal payout/replay operation processing (S14). In this process, if the symbol combination determined in the winning operation determination process described above is a combination of symbols related to a small role, the corresponding number of medals will be paid out, and if it is a combination of symbols related to a replay role, the number of medals will be paid out for the next time. Performs various processes necessary to activate replay in a game. For example, if the symbol combination determined in the winning operation determination process described above is a symbol combination related to a replay combination, the same value as the number of bets in the current game is set in the automatic insertion medal counter described below. Perform the processing to do. Further, in this process, a medal payout signal corresponding to the number of medals to be paid out is output from the external centralized terminal board 55.

Next, the main CPU 101 performs a game end state control process (S15). In this process, for each game state, when a game ends, if a transition condition is satisfied (for example, based on a combination of displayed symbols, etc.), the game state is transitioned according to the established transition condition. , or perform various processes necessary to manage the gaming period of the current gaming state. The details of the state control process at the end of the game will be described later.

Subsequently, the main CPU 101 performs main side performance control processing at the end of the game (S16). In this process, when various effects are to be performed under the control of the main control circuit 100 (main side) when the game ends, various processes necessary for performing the effects are performed. For example, when a lock effect is performed at the end of a game, execution of the lock effect is controlled. Furthermore, if this includes a pseudo game, the progress of the pseudo game (or notification regarding the pseudo game) is controlled. Further, although the details are omitted, when a lock effect is performed, a lock command generation and storage process is performed in this process.

In this way, in the pachi-slot machine 1, one unit game is controlled by performing the above-described processes S2 to S16, and the progress of the game is controlled by repeating these processes. Note that the configuration may be such that processes other than these processes are performed as necessary, or the configuration may be configured such that some of these processes are not performed. That is, the various processes described above are merely examples.

(Processing at power-on)
Next, with reference to FIG. 24, the power-on process performed in S1 of the above-mentioned main process will be described. Note that FIG. 24 is a flowchart illustrating an example of the procedure of power-on processing.

First, the main CPU 101 performs an initialization process (not shown) upon power-on, then performs a write test on the main RAM 103, and determines whether or not the write to the main RAM 103 has been performed normally as a result of the test. S21). That is, the main CPU 101 determines whether or not an abnormality has occurred in the main RAM 103.

If the main CPU 101 determines that the writing to the main RAM 103 has been performed normally (S21: YES), the main CPU 101 determines whether the setting key-type switch 52 is in the on state (S22). That is, the main CPU 101 determines whether or not the settings can be changed.

If the main CPU 101 determines that the setting key-type switch 52 is in the on state (YES in S22), it performs initialization processing when changing settings (S23). In this process, the data in the designated storage area in the main RAM 103 is cleared. The designated storage area here is, for example, a carryover combination storage area, a gaming state flag storage area, a mode flag storage area, or other storage area where data needs to be erased when changing settings.

Next, the main CPU 101 performs initialization command generation and storage processing (S24). In this process, initialization command data indicating that the setting change process to be sent to the sub-control circuit 200 has been started is generated, and the generated data is stored in the communication data storage area.

Next, the main CPU 101 performs a setting change process (S25). In this process, after the main RAM 103 is initialized by accepting the above-mentioned setting value determination operation and setting value confirmation operation, new setting values are set (stored) in a setting value storage area (not shown) of the main RAM 103. be done. Next, the main CPU 101 determines whether the setting key-type switch 52 is turned off (S26). That is, after a new setting value is set, the main CPU 101 determines whether or not the state in which settings can be changed has ended.

If the main CPU 101 determines that the setting key-type switch 52 is not in the OFF state (NO in S26), the main CPU 101 waits for processing until the setting key-type switch 52 is in the OFF state. On the other hand, if it is determined that the setting key-type switch 52 is in the off state (S26: YES), initialization command generation and storage processing is performed (S27). In this process, initialization command data indicating that the setting change process to be sent to the sub-control circuit 200 has been completed is generated, and the generated data is stored in the communication data storage area. After this process, the main CPU 101 ends the power-on process.

If the main CPU 101 determines in S22 that the setting key-type switch 52 is not in the on state (NO in S22), the main CPU 101 determines whether the backup data is normal (S28). That is, the main CPU 101 determines whether the various information backed up when the power supply to the pachi-slot machine 1 is cut off (at the time of power outage) is normal.

When the main CPU 101 determines that the backup data is normal (S28: YES), the main CPU 101 performs a game return process (S29). In this process, the pachi-slot machine 1 is returned to the state before the power cutoff. After this process, the main CPU 101 ends the power-on process.

If the main CPU 101 determines in S21 that writing to the main RAM 103 was not performed normally (NO in S21), and if it determines in S28 that the backup data is not normal (NO in S28), an error occurs when the power is turned on. Processing is performed (S30). It should be noted that the error generated by this power-on error processing is not resolved by the above-mentioned reset operation, but is resolved in response to a new set value being set. Therefore, after the power-on error process, the pachi-slot machine 1 is powered off, and then the main CPU 101 operates normally until a new set value is set (until the above-mentioned processes S22 to S26 are performed). The process does not proceed (S2 and subsequent steps in FIG. 23).

(Medal reception/start check processing)
Next, with reference to FIG. 25, the medal reception/start check process performed in S3 of the above-mentioned main process will be described. Note that FIG. 25 is a flowchart showing an example of the procedure of the medal reception/start check process.

First, the main CPU 101 determines whether the value of the automatic insertion medal counter is "0" (S41). That is, the main CPU 101 determines whether or not a replay winning combination was won in the previous unit game (replay was activated).

When the main CPU 101 determines that the value of the automatic insertion medal counter is not "0" (NO in S41), the main CPU 101 performs automatic insertion processing (S42). In this process, the same number of medals as the medals inserted in the previous unit game are automatically inserted. Further, although details are omitted, when automatic insertion is performed, medal insertion command generation and storage processing is performed in this process. Also, in this process, a medal input signal is output from the external centralized terminal board 55.

If the main CPU 101 determines in S41 that the value of the automatic medal counter is "0" (YES in S41), and after the process in S42, it performs a medal auxiliary storage switch check process (S43). In this process, it is determined whether the medal auxiliary storage switch 33S is turned on (that is, whether a certain number or more of medals are stored in the medal auxiliary storage 33), and the medal auxiliary storage switch 33S is turned on. If it is determined that it is in the on state, a medal auxiliary storage error is generated. In this case, processing is put on hold until the error is resolved. Further, if it is determined that the medal auxiliary storage switch 33S is not in the on state, this process is ended.

Next, the main CPU 101 performs a medal insertion state check process (S44). In this process, the current number of bets and credits are checked, and it is also determined whether acceptance of medals is prohibited or a selector error has occurred, and if it is possible to accept medals, the number of medals is Set the state to a state in which reception is possible (state in which bet operations can be received) (to permit reception of medals). Note that if a selector error has occurred, the process is on standby until the error is resolved.

Next, the main CPU 101 determines whether or not it is possible to accept medals (S45). When the main CPU 101 determines that medals can be accepted (S45: YES), the main CPU 101 performs a medal insertion check process (S46). In this process, the number of bets and the number of credits are updated based on the detection results of the medal sensor 31S and the bet switch 6S. Further, although details are omitted, when a bet operation is performed, a medal insertion command generation and storage process is performed in this process. Also, in this process, a medal input signal is output from the external centralized terminal board 55.

Next, the main CPU 101 determines whether or not medal insertion or credit is possible (S47). That is, the main CPU 101 determines whether the number of bets is "3" and the number of credits is not "50". When the main CPU 101 determines that it is not possible to insert medals or credit (that is, the number of bets is "3" and the number of credits is also "50") (S49 is NO) , prohibits acceptance of medals (S48). That is, the main CPU 101 is in a state where it is not possible to accept medals (a state where it is not possible to accept bet operations).

If the main CPU 101 determines in S45 that it is not possible to accept medals (NO in S45), in S47 it determines that it is possible to insert medals or credit (YES in S47), After the process of S48, it is determined whether the number of inserted coins is the number of coins that can start playing (S49). In the case of the first gaming machine, in this process, for example, it is determined whether the current number of bets is "2" or "3".

If the main CPU 101 determines that the number of coins inserted is the number of coins that can be used to start the game (S49: YES), the main CPU 101 determines whether the start switch 7S is turned on (S50). That is, the main CPU 101 determines whether or not the player has performed a start operation.

If the main CPU 101 determines that the start switch 7S is turned on (S50: YES), it prohibits the acceptance of medals (S51). After this process, the main CPU 101 ends the medal reception/start check process.

If the main CPU 101 determines in S49 that the number of coins inserted is not the number that can start the game (NO in S49), and if it determines in S50 that the start switch 7S is not in the on state (NO in S50), the main CPU 101 performs processing. is returned to S44.

(Internal lottery processing)
Next, with reference to FIG. 26, the internal lottery process performed in S5 of the above-mentioned main process will be described. Note that FIG. 26 is a flowchart showing an example of the procedure of the internal lottery process.

First, the main CPU 101 performs a process of checking the set value and the number of inserted medals (S61). In this process, the setting value and the number of bets in the current unit game are checked. Next, the main CPU 101 sets an internal lottery table according to the set value, the number of bets, the gaming state, etc. (S62). Next, the main CPU 101 obtains an internal lottery random number value from the random number storage area (S63). That is, the main CPU 101 acquires the data of the internal lottery random number value acquired in S4 of the above-described main process. In addition, in this process, if it is determined that the set value is other than "1" to "6" or the number of bets is other than "1" to "3", the main CPU 101 determines that a serious error has occurred. Then, the above-mentioned power-on error process (see S30 in FIG. 24) is executed.

Next, the main CPU 101 performs internal winning combination determination processing (S64). In this process, the obtained internal lottery random number value is sequentially updated (for example, by addition update) using the lottery value of each internal lottery combination specified in the internal lottery table that has been set, and the updated result becomes a predetermined result. (for example, overflowed). When a predetermined result is obtained, the internal winning combination is determined as the internal winning combination of the current unit game. Note that if the predetermined result is not obtained even after determining all the internal winning combinations, the result of the current unit game will be a "loss" (a "loss" will be determined as the internal winning combination).

Subsequently, the main CPU 101 determines whether an internal winning combination has been determined (S65). When the main CPU 101 determines that the internal winning combination has not been determined (S65 is NO), the process returns to S64. In other words, the main CPU 101 sequentially updates the internal winning combinations to be determined (and sequentially updates the random numbers for internal lottery) until all internal winning combinations are determined (or if the internal winning combinations are determined midway through the process). (until it is determined) the process of S64 is repeated.

When the main CPU 101 determines that the internal winning combination has been determined (S65 is YES), the main CPU 101 determines whether the determined internal winning combination is a non-carryover combination (that is, it is not a bonus combination that is a carryover combination, but is a small combination or a replay combination). It is determined whether or not it is a winning combination (S66). When the main CPU 101 determines that the determined internal winning combination is a non-carryover winning combination (S66: YES), the main CPU 101 updates the winning flag storage area (S67). In this process, data in the winning flag storage area is updated based on the internal winning combination determined in the process of S64. That is, the main CPU 101 stores "1" in the bit in the winning flag storage area in the data corresponding to the symbol combination that is permitted to be displayed in accordance with the determined internal winning combination.

If the main CPU 101 determines in S66 that the determined internal winning combination is not a carryover winning combination (NO in S66), and after the processing in S67, it determines whether the determined internal winning combination is a carryover winning combination ( In other words, it is determined whether the winning combination is a carryover bonus winning combination (S68).

When the main CPU 101 determines that the determined internal winning combination is a carryover target combination (S68: YES), the main CPU 101 determines whether the data in the carryover combination storage area is "0" (S69). That is, the main CPU 101 determines whether any bonus combinations have not been carried over yet. If the main CPU 101 determines that the data in the carryover combination storage area is "0" (S69 is YES), it updates the carryover combination storage area (S70). In this process, data in the carryover winning combination storage area is updated based on the internal winning combination determined in the processing of S64. That is, the main CPU 101 stores "1" in the bit in the carryover combination storage area in the data corresponding to the symbol combination that is permitted to be displayed in accordance with the determined internal winning combination.

If the main CPU 101 determines in S68 that the determined internal winning combination is not a carryover winning combination (S68 is NO), then in S69 it determines that the data in the carryover combination storage area is not "0" (S69 is NO). ), and after the processing in S70, it is determined again whether the data in the carryover winning combination storage area is "0" (S71).

If the main CPU 101 determines that the data in the carryover combination storage area is not "0" (S71: NO), it updates the winning flag storage area (S72). In this process, the data stored in the carryover combination storage area is reflected in the data in the winning flag storage area. That is, when the bonus combination has been carried over (or won in the current unit game), the main CPU 101 stores data corresponding to the symbol combinations that are permitted to be displayed in correspondence with the bonus combination in the winning flag storage area. ``1'' is stored in the bit.

If the main CPU 101 determines in S71 that the data in the carryover combination storage area is "0" (S71 is YES), and after the process in S72, it performs a sub-flag etc. setting process (S73). In the case of the first gaming machine, in this process, for example, a non-advantageous section sub-flag and an advantageous section winning sub-flag are set based on the internal winning combination. Note that in this process, for example, when in the AT state, information corresponding to information on a stop operation notified by the instruction monitor may be set. After this process, the main CPU 101 ends the internal lottery process.

(Game start state control processing)
Next, with reference to FIG. 27, the game start state control process performed in S6 of the above-mentioned main process will be described. Note that FIG. 27 is a flowchart showing an example of the procedure of the game start state control process.

First, the main CPU 101 performs a game state transition condition satisfaction check process (S81). In this process, when starting a game, it is checked whether transition conditions for transitioning from any gaming state to any gaming state are satisfied. For example, when shifting to a flag as a predetermined RT state based on winning a predetermined bonus combination, it is checked in this process whether or not the predetermined bonus combination has been won. Note that in the case of the first gaming machine, since the space between the flags is not configured as an RT state (that is, as a gaming state stored in the gaming state flag storage area), there is no need to check here. Further, for example, if there is a specific RT state that starts or ends when a specific number of games are played after the establishment of a specific transition condition, this specific number of games can be managed in this process.

Subsequently, the main CPU 101 determines whether a transition condition for transitioning to any gaming state is satisfied (S82). If the main CPU 101 determines that the transition condition for transitioning to any gaming state is satisfied (S82 is YES), the main CPU 101 updates the gaming state flag storage area (S83). That is, the main CPU 101 sets the gaming state according to the established transition condition. Next, the main CPU 101 performs a setting process according to the set gaming state (S84). In this process, depending on the transition of the gaming state, for example, it is necessary to set the gaming period of the gaming state, or to set the lottery value (lottery table) for various lottery processes other than the internal lottery process. In such cases, such setting processing is performed as appropriate.

If the main CPU 101 determines in S82 that the transition conditions for transitioning to any gaming state are not satisfied (NO in S82), and after the processing in S84, the current gaming section is a non-advantageous section. It is determined whether there is one (S85). If the main CPU 101 determines that the current game section is a non-advantageous section (S85: YES), it performs a process of checking whether the start condition for an advantageous section is established (S86). In this process, when starting a game, it is checked whether transition conditions for transitioning from a non-advantageous section to an advantageous section (starting conditions for an advantageous section) are satisfied. In the case of the first gaming machine, in this process, for example, the above-mentioned advantageous section transition lottery is performed, and it is checked whether or not this lottery result is the one that starts the advantageous section.

Next, the main CPU 101 determines whether the start condition for the advantageous section is satisfied (S87). If the main CPU 101 determines that the conditions for starting the advantageous section are not satisfied (NO in S87), the main CPU 101 ends the game start state control process. Further, when the main CPU 101 determines that the conditions for starting the advantageous section are satisfied (S87: YES), the main CPU 101 performs a setting process at the start of the advantageous section (S88). That is, the main CPU 101 starts (sets) the advantageous section. In this process, in response to the start of an advantageous section, for example, various counters (see FIG. 16) related to various limit processes start counting (that is, start monitoring the gaming period of a series of advantageous sections), etc. Perform the setting process as appropriate.

Next, the main CPU 101 updates the mode flag storage area (S89). That is, the main CPU 101 sets the mode (gaming state) during the started advantageous section. In the case of the first gaming machine, in this process, for example, the destination mode determined according to the lottery result of the above-mentioned advantageous section transition lottery is set.

Next, the main CPU 101 performs setting processing according to the set mode (S90). In this process, depending on the set mode, the game period of the mode (including the number of ceiling games, etc.) is set, and the lottery values (lottery table) for various lottery processes other than the internal lottery process are set. If necessary, such setting processing is performed as appropriate. In the case of the first gaming machine, in this process, for example, in accordance with the set destination mode, when transitioning to a pseudo bonus, "55 games" is set as the gaming period, and the game transitions to the end mode. In this case, "32 games" is set as the game period, and in the case of transitioning to other modes, the corresponding number of ceiling games is set. In addition, lottery values (lottery table) for various types of lottery (see FIGS. 7 and 8, etc.) are set. After this process, the main CPU 101 ends the game start state control process.

If the main CPU 101 determines in S85 that the current gaming section is not a non-advantageous section (that is, it is an advantageous section) (S85: NO), it performs processing at the start of a game during an advantageous section (S91). The details of the processing at the start of the game during the advantageous section will be described later.

Next, the main CPU 101 performs a process to check whether the advantageous section end condition is met (S92). In this process, when starting a game, it is checked whether transition conditions for transitioning from an advantageous section to a non-advantageous section (conditions for ending the advantageous section) are satisfied. In the case of the first gaming machine, in this process, for example, it is determined whether the operating conditions for various limit processes are satisfied based on the number of games in the advantageous period (see FIG. 16), or if the current mode is the end mode. In this step, it is checked whether 32 games have elapsed or not.

Next, the main CPU 101 determines whether the conditions for ending the advantageous section are satisfied (S93). If the main CPU 101 determines that the conditions for ending the advantageous section are satisfied (S93: YES), the main CPU 101 performs initialization processing at the end of the advantageous section (S94). That is, the main CPU 101 ends the advantageous section and sets a non-advantageous section. In this process, depending on the end of the advantageous period, for example, various counters related to various limit processes (see FIG. 16), the mode (playing state) during the advantageous period, and the playing period of the mode (the number of ceiling games, etc.) are displayed. Initialization processing is performed to clear all information related to (including information on advantageous sections) etc. (that is, information related to advantageous sections). After this process, the main CPU 101 ends the game start state control process. Further, when the main CPU 101 determines that the end condition for the advantageous section is not satisfied (S93 is NO), the main CPU 101 ends the game start state control process.

(Processing at the start of the game during the advantageous section)
Next, with reference to FIG. 28, the advantageous section game start process performed in S91 of the game start state control process described above will be described. Note that FIG. 28 is a flowchart showing an example of the procedure of the processing at the start of the game during the advantageous section.

First, the main CPU 101 performs various counter updating processes (at the start of the game) (S101). In this process, for example, various counters related to various limit processes based on the number of games during the advantageous period (see FIG. 16), various counters for managing the gaming period such as various modes (playing states) during the advantageous period, or other counters are used. Various counters that manage the degree of advantage are updated according to predetermined update conditions (for example, subtraction (addition) by 1 for each game, etc.).

Next, the main CPU 101 determines whether or not the specific mode (AT state) is in progress (S102). If the main CPU 101 determines that it is in the specific mode (YES in S102), it performs AT period management processing (at the start of the game) (S103). In this process, for example, when it is possible to extend the playing period in the AT state (for example, by extending the number of games or adding the number of sets) at the start of the game, it is determined whether the execution conditions for such an extension are satisfied or not. Based on the result of this determination, processing such as extending the gaming period is performed (if it is possible to shorten the playing period in the AT state, processing related to the shortening is performed). In addition, in this process, the AT state gaming period may be managed regardless of whether it is extended or not, or the AT state gaming period is managed in the process of S101 described above, and this process only deals with the extension. may be performed. In the case of the first gaming machine, in this process, for example, the above-mentioned 1G consecutive lottery is performed based on the advantageous section winning sub-flag, the 1G consecutive lottery is performed, and the pseudo bonus is extended according to the lottery result. Processing is performed for this purpose.

Next, the main CPU 101 performs navigation setting processing (S104). In this process, information corresponding to the stop operation information notified by the instruction monitor, information corresponding to the stop operation information included in the start command, etc. are set. Note that in this process, it may be possible to determine whether or not to generate navigation. In other words, when the notification target winning combination is won in the AT state, navigation may not necessarily occur. The determination may be made according to the probability of occurrence).

When the main CPU 101 determines in S102 that the specific mode is not in progress (NO in S102), and after S104, the main CPU 101 determines whether a mode transition condition is satisfied (S105). In the case of the first gaming machine, in this process, for example, it is determined whether the destination mode has been determined according to the lottery result of the mode transition lottery described above based on the advantageous section winning time sub-flag.

When the main CPU 101 determines that the mode transition condition is satisfied (YES in S105), the main CPU 101 updates the mode flag storage area (S106). That is, the main CPU 101 sets the mode (gaming state) in the advantageous section to which the mode has been transferred. In the case of the first gaming machine, in this process, for example, the destination mode is set, which is determined according to the lottery result of the mode transition lottery described above based on the advantageous section winning time sub-flag.

Next, the main CPU 101 performs setting processing according to the set mode (S107). In this process, depending on the set mode, the game period of the mode (including the number of ceiling games, etc.) is set, and the lottery values (lottery table) for various lottery processes other than the internal lottery process are set. If necessary, such setting processing is performed as appropriate. Note that in the case of the first gaming machine, in this process, for example, a process similar to the process of S90 described above is performed. After this process, the main CPU 101 ends the process at the start of the game during the advantageous section. Further, when the main CPU 101 determines that the mode transition condition is not satisfied (NO in S105), the main CPU 101 ends the processing at the start of the game during the advantageous section.

The state control process at the start of the game shown in FIG. 27, the state control process at the end of the game shown in FIG. 30, the process at the start of the game during the advantageous period shown in FIG. 28, and the process at the end of the game during the advantageous period shown in FIG. Basically, they have almost the same processing configuration. This process may be performed either when the game starts or when the game ends (for example, a process that refers to the determined internal winning combination, such as changing the game state or mode, etc.) Processing where the processing result only needs to be reflected until the end of the current game (or until the start of the next game) means that it only needs to be performed in either one, and the same applies to both. This does not mean that the processing is performed redundantly. Therefore, such processing may be performed either when the game starts or when the game ends.

On the other hand, processing that needs to be performed when starting a game (for example, the above-mentioned navigation setting process, etc.) shall be performed when starting the game, and when the game ends. Processing that needs to be performed (for example, processing that refers to the combination of displayed symbols) may be performed when the game ends. Also, for example, there are cases where processing needs to be performed at a predetermined time after the start of the game and before the end of the game, or cases where it is better to perform the process (for example, a process that refers to the stop operation mode of the first stop operation, etc.) ) may be carried out at that time.

(Reel stop control process)
Next, with reference to FIG. 29, the reel stop control process performed in S12 of the above-mentioned main process will be described. Note that FIG. 29 is a flowchart showing an example of the procedure of the reel stop control process.

First, the main CPU 101 determines whether the rotational speeds of all the reels have reached a predetermined constant speed (for example, 80 rotations/minute) (that is, whether they are rotating at a constant speed) (S111). If the main CPU 101 determines that all the reels are not rotating at a constant speed (NO in S111), the main CPU 101 waits for processing until all the reels are rotating at a constant speed. On the other hand, if it is determined that all the reels are rotating at a constant speed (S111: YES), each reel is allowed to stop (S112). That is, the main CPU 101 activates each stop button. Additionally, the operation stop button storage area is updated accordingly (in the case of the first gaming machine, for example, "1" is stored in bits 4 to 6 of the operation stop button storage area).

Next, the main CPU 101 determines whether a valid stop button has been operated (S113). If the main CPU 101 determines that a valid stop button has not been operated (NO in S113), the main CPU 101 waits for processing until a valid stop button is operated. In addition, when performing automatic stop control, the standby time can be measured and the automatic stop control can be performed when the measurement result reaches a predetermined time.

If the main CPU 101 determines that a valid stop button has been operated (YES in S113), the main CPU 101 updates the operation stop button storage area and the pressing order storage area (S114). In the case of the first gaming machine, for example, when the first stop operation is performed on the reel 3L (when the stop button 8L is pressed), in this process, the bits in the operation stop button storage area are "1" is stored in 0, and bit 4 is updated to "0". Further, bits 2 to 5 of the pressing order storage area are updated to "0".

Next, the main CPU 101 determines the reel to be controlled from the operation stop button (S115). In this process, for example, when the stop button 8L is pressed, the reel 3L is determined as the reel to be controlled.

Next, the main CPU 101 stores the stop start position from the symbol counter (S116). The symbol counter is configured as a counter for grasping symbol position data (for example, "0" to "19"). In this process, for example, when the stop button 8L is pressed, the symbol position data of the middle region of the reel 3L at the time the stop button 8L is pressed is stored as the stop start position.

Next, the main CPU 101 performs sliding piece number determination processing (S117). In this process, for example, the most appropriate number of sliding pieces (symbol movement amount) is determined by referring to the number of sliding pieces specified in the above-mentioned stop table, the data in the above-mentioned attraction priority data storage area, etc.

Next, the main CPU 101 stores the scheduled stop position from the stop start position and the number of sliding pieces (S118). In this process, the symbol position data of the position where the symbol will finally stop based on the stop start position stored in the process of S116 described above and the number of sliding pieces determined in the process of S117 described above is stored as the planned stop position. .

Next, the main CPU 101 performs reel stop command generation and storage processing (S119). In this process, data for a reel stop command to be sent to the sub-control circuit 200 is generated, and the generated data is stored in a communication data storage area provided in the main RAM 103. Note that the reel stop command can include parameters that can specify not only the scheduled stop position but also the stop start position and the number of sliding pieces.

Next, the main CPU 101 performs symbol code storage processing (S120). In this process, the symbol code storage area is updated while also referring to the symbol type (symbol code) of the scheduled stop position on the reel whose scheduled stop position has already been determined. Next, the main CPU 101 determines whether there is a valid stop button (S121). That is, the main CPU 101 determines whether there are any reels that are still rotating (whether or not a stop operation has been performed on all reels).

If the main CPU 101 determines that there is a valid stop button (YES in S121), it performs control change processing (S122). In this process, depending on the player's stop operation mode up to this point, for example, if it is necessary to change the stop table, attraction priority table, etc. set in the above-mentioned reel stop initial setting process, such changes may be made. Reset various information necessary for stop control.

Next, the main CPU 101 performs an attraction priority order storage process (S123). In this process, each symbol (symbol position) on the rotating reels is set as the set internal winning combination while also referring to the type of symbol at the scheduled stop position on the reel whose scheduled stop position has already been determined. The data indicating the attraction priority is obtained by referring to the attraction priority order table, and is stored in the attraction priority order data storage area. After this process, the main CPU 101 returns the process to S113. Further, when the main CPU 101 determines that there is no valid stop button (NO in S121), the main CPU 101 ends the reel stop control process.

(Status control process at game end)
Next, with reference to FIG. 30, the game end state control process performed in S15 of the above-mentioned main process will be described. Note that FIG. 30 is a flowchart showing an example of the procedure of the state control process at the end of the game.

First, the main CPU 101 performs a game state transition condition satisfaction check process (S131). In this process, when the game ends, it is checked whether transition conditions for transitioning from any gaming state to any gaming state are satisfied. For example, when transitioning to a predetermined RT state or a predetermined bonus state based on the display of a predetermined symbol combination, a check is performed in this process to see if the predetermined symbol combination is displayed. Furthermore, if the game is in a predetermined RT state or a predetermined bonus state, it is checked in this process whether or not the termination conditions for these gaming states are satisfied. In the case of the first gaming machine, in this process, for example, it is checked whether a combination of symbols related to 2BB or 3BB is displayed. Further, for example, in the case of the 2BB state or the 3BB state, it is checked whether or not the end conditions of these gaming states are satisfied by the payout of medals.

Next, the main CPU 101 determines whether a transition condition for transitioning to any gaming state is satisfied (S132). If the main CPU 101 determines that the transition condition for transitioning to any gaming state is satisfied (S132 is YES), the main CPU 101 updates the gaming state flag storage area (S133). That is, the main CPU 101 sets the gaming state according to the established transition condition. In the case of the first gaming machine, in this process, for example, when a combination of symbols related to 2BB or 3BB is displayed, "1" is stored in bit 0 or bit 1 of the gaming status flag storage area, and Set state or 3BB state. Further, for example, in the case of the 2BB state or the 3BB state, if the termination conditions of these gaming states are satisfied, bit 0 or bit 1 of the gaming state flag storage area is updated to "0".

Next, the main CPU 101 performs a setting process according to the set gaming state (S134). In this process, depending on the transition of the gaming state, for example, it is necessary to set the gaming period of the gaming state, or to set the lottery value (lottery table) for various lottery processes other than the internal lottery process. In such cases, such setting processing is performed as appropriate. In the case of the first gaming machine, in this process, for example, if the 2BB state is set, the number of payouts as the end condition is set to "1", and even if the 3BB state is set, the number of payouts is set to "1". For example, "176" is set as the number of payouts as the end condition.

If the main CPU 101 determines in S132 that the transition condition for transitioning to any gaming state is not satisfied (S132 is NO), and after the processing in S134, the current gaming section is a non-advantageous section. It is determined whether there is one (S135). When the main CPU 101 determines that the current game section is a non-advantageous section (S135: YES), it performs a process of checking whether the conditions for starting the advantageous section are established (S136). As described above, in the non-advantageous section, only the process that refers to the determined internal winning combination is possible, so this process is similar to the process of S86 (game start state control process) described above.

Next, the main CPU 101 determines whether the start condition for the advantageous section is satisfied (S137). If the main CPU 101 determines that the starting conditions for the advantageous section are not satisfied (S137 is NO), the main CPU 101 ends the game end state control process. Further, when the main CPU 101 determines that the conditions for starting the advantageous section are satisfied (YES in S137), the main CPU 101 performs a setting process for starting the advantageous section (S138). Note that, as described above, in the non-advantageous section, only the process that refers to the determined internal winning combination is possible, so this process is similar to the process of S88 (game start state control process) described above.

Next, the main CPU 101 updates the mode flag storage area (S139). That is, the main CPU 101 sets the mode (gaming state) during the started advantageous section. Note that, as described above, in the non-advantageous section, only the process that refers to the determined internal winning combination is possible, so this process is similar to the process of S89 described above (game start state control process).

Next, the main CPU 101 performs setting processing according to the set mode (S140). In this process, depending on the set mode, the game period of the mode (including the number of ceiling games, etc.) is set, and the lottery values (lottery table) for various lottery processes other than the internal lottery process are set. If necessary, such setting processing is performed as appropriate. As mentioned above, in the non-advantageous section, only the process that refers to the determined internal winning combination is possible, so this process is similar to the process of S90 (game start state control process) described above.

If the main CPU 101 determines in S135 that the current game section is not a non-advantageous section (that is, it is an advantageous section) (S135: NO), it performs processing at the end of the game during the advantageous section (S141). The details of the processing at the end of the game during the advantageous section will be described later.

Subsequently, the main CPU 101 performs a process of checking whether conditions for ending the advantageous section are met (S142). In this process, when the game ends, it is checked whether transition conditions for transitioning from an advantageous section to a non-advantageous section (end conditions for an advantageous section) are satisfied. In addition, in the case of the first gaming machine, in this process, for example, it is determined whether the operating conditions of various limit processes are satisfied based on the number of payouts during the advantageous section (see FIG. 16), or if the current mode is the end mode. In this step, it is checked whether 32 games have elapsed or not.

Next, the main CPU 101 determines whether the conditions for ending the advantageous section are satisfied (S143). If the main CPU 101 determines that the conditions for ending the advantageous section are met (S143: YES), the main CPU 101 performs initialization processing at the end of the advantageous section (S144). That is, the main CPU 101 ends the advantageous section and sets a non-advantageous section. In this process, depending on the end of the advantageous period, for example, various counters related to various limit processes (see FIG. 16), the mode (playing state) during the advantageous period, and the playing period of the mode (the number of ceiling games, etc.) are displayed. Initialization processing is performed to clear all information related to (including information on advantageous sections) etc. (that is, information related to advantageous sections). After this process, the main CPU 101 ends the game end state control process. Further, when the main CPU 101 determines that the conditions for ending the advantageous section are not satisfied (S143: NO), the main CPU 101 ends the game end state control process.

(Processing at the end of the game during the advantageous section)
Next, with reference to FIG. 31, the processing at the end of the game during the advantageous section performed in S141 of the above-mentioned state control processing at the end of the game will be described. Note that FIG. 31 is a flowchart showing an example of the procedure of the processing at the end of the game during the advantageous section.

First, the main CPU 101 performs various counter updating processes (at the end of the game) (S151). In this process, for example, various counters related to various limit processes based on the number of payouts during an advantageous period (see FIG. 16), various counters for managing gaming periods such as various modes (gaming states) during an advantageous period, or other counters are used. Various counters that manage the degree of advantage are updated according to predetermined update conditions (for example, the number of payouts, the number of times a predetermined combination of symbols is displayed, the stop operation mode, etc.).

Next, the main CPU 101 determines whether or not it is in a specific mode (AT state) (S152). If the main CPU 101 determines that it is in the specific mode (S152: YES), it performs AT period management processing (at the end of the game) (S153). In this process, for example, when it is possible to extend the AT state playing period (for example, by extending the number of games or adding the number of sets) at the end of the game, it is determined whether the execution conditions for such an extension are satisfied or not. Based on the result of this determination, processing such as extending the gaming period is performed (if it is possible to shorten the playing period in the AT state, processing related to the shortening is performed). In addition, in this process, the AT state gaming period may be managed regardless of whether it is extended or not, or the AT state gaming period is managed in the process of S151 described above, and this process only deals with the extension. may be performed. In the case of the first gaming machine, in this process, for example, the above-mentioned 1G continuous lottery is performed based on the advantageous section winning time sub-flag, and a process for extending the pseudo bonus is performed according to the result of this lottery.

If the main CPU 101 determines that the specific mode is not in progress (S152 is NO), and after S153, the main CPU 101 determines whether mode transition conditions are satisfied (S154). In the case of the first gaming machine, in this process, for example, it is determined whether the destination mode has been determined according to the lottery result of the mode transition lottery described above based on the advantageous section winning time sub-flag.

When the main CPU 101 determines that the mode transition condition is satisfied (S154 is YES), the main CPU 101 updates the mode flag storage area (S155). That is, the main CPU 101 sets the mode (gaming state) in the advantageous section to which the mode has been transferred. In the case of the first gaming machine, in this process, for example, the destination mode is set, which is determined according to the lottery result of the mode transition lottery described above based on the advantageous section winning time sub-flag.

Next, the main CPU 101 performs setting processing according to the set mode (S156). In this process, depending on the set mode, the game period of the mode (including the number of ceiling games, etc.) is set, and the lottery values (lottery table) for various lottery processes other than the internal lottery process are set. If necessary, such setting processing is performed as appropriate. Note that in the case of the first gaming machine, in this process, for example, a process similar to the process of S140 described above is performed. After this process, the main CPU 101 ends the process at the end of the game during the advantageous section. Further, when the main CPU 101 determines that the mode transition condition is not satisfied (S154 is NO), the main CPU 101 ends the processing at the end of the game during the advantageous section.

[6-2. Periodic interrupt processing]
First, with reference to FIG. 32, periodic interrupt processing executed by the main CPU 101 of the main control circuit 100 will be described. Note that FIG. 32 is a flowchart showing an example of the procedure of periodic interrupt processing.

Here, in this embodiment, the period of periodic interrupt processing (one interrupt time) is set to "1.1172 ms". However, the cycle of periodic interrupt processing is not limited to this. For example, periodic interrupt processing may be executed at a different cycle, or even if the same cycle is set, the interrupt processing may actually be executed for some or all of the processing. By setting the number of interrupts to "2" or more, the periodic interrupt process may be executed at a different cycle as a result.

First, the main CPU 101 performs register saving processing (S201). Next, the main CPU 101 performs input port check processing (S202). In this process, the input states (on state or off state) of various sensors and switches connected to the main control board 71 (including those connected via the main relay board 73) are checked. For example, the input state at the time of the previous interrupt and the input state at the time of the current interrupt are compared to check whether there has been a change in the input state, and if there is a change in the input state, the input state of the main RAM 103 is The change is stored in port storage area 0 (not shown), and input states that are not related to the change are stored as they are in input port storage area 1 (not shown) of the main RAM 103.

Next, the main CPU 101 performs reel control processing (S203). In this process, the driving of each stepping motor 51L, 51C, 51R is controlled, and the rotation and stop of each reel 3L, 3C, 3R is controlled. Next, the main CPU 101 performs communication data transmission processing (S204). In this process, each parameter of each command stored in the communication data storage area is transmitted to the sub control circuit 200. In this process, if no command data is stored in the communication data storage area, the data stored in input port storage area 0 and input port storage area 1 is sent to the sub control circuit 200 as an input status command.

Note that in this embodiment, various command data are once stored in the communication data storage area and then transmitted to the sub-control circuit 200 in periodic interrupt processing. It may be configured such that the information is not stored but is directly stored in a communication circuit (not shown) provided in the main control circuit 100 and transmitted to the sub control circuit 200. Further, in this embodiment, although detailed explanation is omitted, various command data are transmitted to the sub control circuit 200 by serial communication. For example, various command data are transmitted to the sub control circuit 200 by parallel communication. It may also be configured such that the information is sent to

Next, the main CPU 101 performs 7-segment LED drive processing (S205). In this process, the display contents of, for example, the information display device 14 connected to the main control board 71 (including those connected via the main relay board 73) are controlled. Next, the main CPU 101 performs timer update processing (S206). In this process, various timers managed by the main control circuit 100 are updated.

Next, the main CPU 101 performs error detection processing (S207). In this process, it is detected whether or not various error states have occurred based on the input state checked in S202 described above. Next, the main CPU 101 performs a door opening/closing check process (S208). In this process, for example, the open/close state of the lower door mechanism DD is checked based on the input state of the door open/close monitoring switch 56. Note that when various error states occur and when the input state of the door opening/closing monitoring switch 56 is in the open state (off state), a security signal is output from the external centralized terminal board 55.

Next, the main CPU 101 performs register restoration processing (S209). After this process, the main CPU 101 ends the periodic interrupt process.

[7. Processing by sub control circuit]
Next, with reference to FIG. 33, an overview of the sub-side control processing executed by the sub CPU 201 of the sub control circuit 200 using each program will be described. FIG. 33 is a flowchart illustrating an example of the outline of the sub-side control process.

In addition, in the Pachislot machine 1, various restrictions are placed on the main control circuit 100 side (including the main control board 71 and the main control board case) from the perspective of preventing fraudulent acts and unauthorized modification. There are not many restrictions on the 200 side (including the sub-control board 72 and the sub-control board case). Therefore, the sub-control board 72 (and the sub-control circuit 200) can be used in various ways depending on the type and number of effect devices to be connected, the type of effect performed by the effect devices, and the manufacturing cost. configuration can be used. That is why it is labeled as "Summary" in FIG. 33.

First, when the power is turned on, the sub CPU 201 performs power-on processing similarly to the main CPU 101 (S301 and S302). This process detects whether an abnormality has occurred when the power is turned on, initializes the data stored in the sub-RAM 203, and performs various tasks necessary to perform various production execution control processes described below. Processing such as starting up is performed.

Further, when the sub CPU 201 receives a command transmitted from the main control circuit 100, it performs a production execution control process upon command reception (S303 and S304). In this process, for example, when an initialization command is received, the parameter information of the received initialization command is referenced, and if settings have been changed, initialization processing is executed on the sub side as appropriate, and the settings must be changed. If so, processing is also executed on the sub side to restore the state to the state before the power cut.

For example, when a start command is received, the parameter information of the received start command is referred to, and if it is in a non-AT state, the content of the production that suggests or informs internal winning combinations, gaming status, etc. (as necessary) (by lottery), and controls various production devices so that the production of the determined content is executed. Furthermore, if it is in the AT state, in addition to this, it determines the content of the performance to notify the advantageous stop operation mode, and controls various performance devices so that the performance of the determined content is executed.

For example, when a lock command is received, it refers to the parameter information of the received lock command, determines the content of the performance that is linked to the content of the lock performance, and creates various performances so that the determined content is executed. Control the device. Also, for example, when a reel stop command is received, the parameter information of the received reel stop command is referred to and linked with the stop start position and planned stop position (or simply the number of stop operations performed, etc.) The content of the performance is determined and various performance devices are controlled so that the performance of the determined content is executed. For example, when a winning activation command is received, the information on the parameters of the received winning activation command is referred to, and when a bonus is awarded, the content of the performance that is linked to the bonus to be awarded is determined, and the determined content is The various presentation devices are controlled so that the presentation is performed.

Further, the sub CPU 201 is connected to the sub-control board 72 (including those connected via the sub-relay board 74), and for example, when the production buttons 10a and 10b are operated, the sub-CPU 201 executes production when the production button is operated. Control processing is performed (S305 and S306). In this process, for example, when a performance button corresponding to the performance is operated during execution of the operation-linked performance, various performance devices are controlled so that the content of the operation-linked performance changes. Further, for example, when a presentation button is operated to call up a user menu, which will be described later, while not playing a game, control is performed to display the user menu. Further, when a presentation button is operated for selection/decision operation while the user menu is displayed, control is performed in accordance with these operations.

Further, when a trigger other than the above-mentioned trigger is established, the sub CPU 201 performs other production execution control processing (S307). In this process, for example, if the non-operation period in which no operation related to the game or user menu is performed is a predetermined period (for example, about 30 seconds), the content of the effect related to the demonstration status notification is determined and determined. The various performance devices are controlled so that the performance of the content is executed.

[8. Other functions of pachislot machines]
As mentioned above, the pachi-slot machine 1 is equipped with various functions for controlling games, various functions for controlling performances, and various configurations for realizing these functions. It can also have functions. Note that an example of other functions on the player side and an example of other functions on the game parlor side will be described below.

[8-1. Player side]
For example, when a user menu is displayed by a player's performance operation, a desired menu is selected in the user menu, and the appropriate selection/decision operation is performed for the selected menu, the player can obtain various information. , it is possible to make various settings.

For example, if "Arrangement/Payout Table" is selected/determined, it is possible to confirm the symbol arrangement in the Pachislot machine 1, the specified symbol combination, and the game information showing the payout (contents of benefits) when winning the prize. The following information screen is displayed on the performance display section.

For example, when "volume/light intensity adjustment" is selected/determined, the brightness of various display devices in the pachislot machine 1, the volume of sound output from the speaker group, the light intensity of the lamp/LED group, etc. are set. A possible setting screen is displayed on the performance display section. In addition, at the time of such settings, in order to enable more detailed settings or to more easily accept operations related to the settings, the various operation sections that accept the player's gaming operations may be It can be used as part of an operation section that accepts operations related to (that is, an operation section that accepts production operations).

For example, when "Custom" is selected/determined, the production mode in the pachislot machine 1 (for example, the type of character used for the production, the type of the character (display mode) itself, the voice corresponding to the character, etc.) or the type of costume or item (individual display mode) related to the character), the probability of production occurrence (including the type of expectation when the production occurs), or the mode of suggestion or notification (production execution timing) etc.) A setting screen is displayed on the effect display section where the settings can be made. In addition, at the time of such settings, in order to enable more detailed settings or to more easily accept operations related to the settings, the various operation sections that accept the player's gaming operations may be It can be used as part of an operation section that accepts operations related to (that is, an operation section that accepts production operations).

Further, for example, when "Unimemo" is selected/determined, it is possible to receive an information provision service using the player's mobile terminal (for example, a mobile phone, a smartphone, etc.). In such information providing services, for example, a player logs in to start a game (it is also possible to start a game without logging in), and when the game ends, logs out, thereby providing gaming history information (e.g. , the total number of games played, how many times an advantageous game state occurred, the maximum number of coins acquired, and other information corresponding to the results of various games) can be confirmed or obtained.

For example, the game history information may include information indicating the types of characters that can be displayed during the game and the types of music that can be output, depending on the game result (the fulfillment of the opening condition), It also includes information about accompanying benefits, such as information indicating the types of characters that can be displayed on the mobile terminal and the types of songs that can be output.

Note that various methods can be used for logging in and logging out in such an information providing service. For example, using the player's terminal, the player may be able to log in and log out by having the player read a two-dimensional code displayed on the effect display section, or the player may enter a password. (Specifically, for example, when logging out at the end of a game, instead of a two-dimensional code, a string of about 4 to 10 digits can be displayed as the password for next input, and The password can be obtained by the player writing it down on paper or taking a photo with a mobile device, etc., and the password obtained in this way can be entered when logging in before the next game starts). - You may be able to log out. Furthermore, it is also possible to perform login and logout by appropriately combining these methods.

[8-2. Game store side]
For example, a hall menu is displayed by a setting confirmation operation (this may be a setting change operation or other operation by the game hall administrator) by the game parlor administrator, and the desired menu is selected from the hall menu. Further, when the selected menu is appropriately selected/determined, the game parlor manager can obtain various information and make various settings.

For example, when "time setting" is selected and determined, a setting screen on which the date and time of the pachi-slot machine 1 can be set is displayed on the production display section. Note that the date and time can also be configured to be automatically updated, for example, in the above-described sub-side power-on process (see S302 in FIG. 33).

For example, when "total medal information" is selected and determined, history information indicating the number of coins inserted and number of coins paid out within a predetermined period (for example, each business day of seven business days) in the pachislot machine 1 is displayed. An information screen that can be confirmed is displayed on the performance display section. Note that such a menu can also be configured as a menu in a user menu.

For example, if "setting change/confirmation history" is selected/determined, the number of setting change operations and setting confirmation operations in the pachislot machine 1 within a predetermined period (for example, each business day for 7 business days), etc. An information screen is displayed on the effect display section where history information indicating the information can be confirmed. For example, if "error information history" is selected/determined, history information indicating the date and time of error occurrence and its contents within a predetermined period (for example, each business day of 7 business days) in the pachislot machine 1 is also provided. An information screen is displayed on the effect display section that allows confirmation of the information.

For example, if "monitoring history" is selected/determined, history information indicating the date and time the door was opened within a predetermined period (for example, each business day of 7 business days), the period, etc. of the pachislot machine 1 is displayed. An information screen that can be confirmed is displayed on the performance display section. Further, for example, when "warning setting" is selected and determined, a setting screen is displayed on the effect display section that allows setting of the mode, frequency, etc. of various warning notifications in the pachi-slot machine 1.

Further, for example, when "power saving mode setting" is selected and determined, a setting screen is displayed on the effect display section that allows settings such as whether or not to activate the power saving function of the pachi-slot machine 1. Note that such a menu can also be configured as a menu in a user menu. In addition, at the time of such settings, in order to enable more detailed settings or to more easily accept operations related to the settings, the various operation sections that accept the player's gaming operations may be It can be used as part of an operation section that accepts operations related to (that is, an operation section that accepts production operations).

Further, for example, when "stop-stop setting" is selected and determined, a setting screen is displayed on the performance display section that allows settings such as whether or not to activate the stop-stop function in the pachi-slot machine 1. Note that the discontinuation function is a function that, when a predetermined operating condition is satisfied, disables the game until a cancellation operation (for example, a reset operation) is performed by the manager of the game parlor. Further, the predetermined operating condition may be established, for example, when the advantageous section is forcibly terminated by executing the above-mentioned limit process, or may be established in a specific state (for example, a bonus state, an increased section, or an advantageous section). It may be made to be established when any of the sections (including the performance section) ends. Moreover, when the cancellation function is set to the ON state, an automatic payment function, which will be described later, may also be set to the ON state in conjunction with this.

Further, for example, when "automatic payment setting" is selected and determined, a setting screen is displayed on the performance display section that allows settings such as whether or not to activate the automatic payment function in the pachi-slot machine 1. Note that the automatic settlement function is a function in which credits are automatically settled (that is, all credited gaming value is automatically returned) when a predetermined operating condition is met. Further, the predetermined operating condition may be established, for example, when the advantageous section is forcibly terminated by executing the above-mentioned limit process, or may be established in a specific state (for example, a bonus state, an increased section, or an advantageous section). It may be made to be established when any of the sections (including the performance section) ends. Moreover, when the automatic payment function is set to the ON state, the above-mentioned cancellation function may also be set to the ON state in conjunction with this.

In addition, when setting the cancellation function or automatic payment function, in order to enable more detailed settings or to more easily accept operations related to settings, various operation sections that accept the player's gaming operations are provided. can be used as part of the operation unit that accepts operations related to the settings (that is, the operation unit that accepts production operations). However, in this case, it is also undesirable to unnecessarily increase the number of operation units that can accept operations, so only a specific operation unit (for example, a stop button) should be used as part of the operation unit that accepts operations related to the setting. It may be possible to do so.

[9. Expansion example]
Up to this point, the pachi-slot machine 1 has been described as an example of a gaming machine to which the invention according to this embodiment can be applied, but the gaming machine to which the invention according to this embodiment can be applied is not limited to this. For example, the present invention can be applied to gaming machines such as so-called "pachinko machines" and "slot machines," and similar effects can be obtained. That is, the invention according to this embodiment can be applied to any gaming machine that is capable of playing a game (performing game control) in accordance with a player's gaming action (operation). Further, the configuration and functions of the gaming machine including the pachi-slot machine 1 are not limited to those described above, and various changes and expansions are possible. An example of such expansion will be described below, although it is just an example.

(pachinko machine)
A pachinko machine includes, for example, a game board having a game area where game balls can roll and fall, a glass door including a protective glass that protects the game area while making it visible from the outside, and an effect display device provided in a predetermined area of the game area. (It may be provided outside the gaming area), a payout unit that pays out game balls, and a board unit that includes various control boards that perform various controls related to games and performances, and these are connected to the frame ( (sometimes simply referred to as a "frame" etc.).

In addition, on the front side of the pachinko machine, for example, there is a firing handle as one of the player's operating means, an upper tray that can store game balls to be used in the game, and a lower tray that can store the game balls that are put out. etc. are provided. Note that many of them are provided with the above-mentioned presentation buttons and movable presentation devices. In addition, the gaming area includes, for example, a starting area (sometimes referred to as a "starting hole" etc.) through which a game ball can pass, a specific area (sometimes referred to as a "V winning hole" etc.), A variable winning device (sometimes referred to as a "big winning hole" etc.) that can change between a state in which it is easy for game balls to win a prize and a state in which it is difficult to win a prize, and identification information (also referred to as a "design" etc.). In some cases, a variable display device or the like is provided that can variably display ``special symbols'' and ``normal symbols''.

In the pachinko machine, a player plays a game by operating a firing handle and firing a game ball into a gaming area. For example, when the fired game ball passes through the starting area, the variable display starts. In addition, at this time, whether or not to transition the gaming state with a probability depending on the current state (for example, whether it is a variable gaming state with a relatively high probability of winning) and the type of starting area, etc. It is determined whether or not to shift to a jackpot gaming state or a small winning gaming state that is advantageous to the player (in other words, it is determined (or determined) whether or not to shift the gaming state). Thereafter, when a condition for stopping the variable display (for example, the set variable time has ended) is satisfied, the variable display is stopped in a stopping manner according to the above determination result. At this time, if the above-determined result is to shift the gaming state (win), the stopping mode to be stopped will also be the display result corresponding to the win, and the corresponding display result will correspond to the win. Shift to the gaming state. On the other hand, if the above-mentioned determination result does not cause the game state to shift (miss), the stopping mode to be stopped also becomes a display result corresponding to the shift, and the game state does not shift. For example, when a fired game ball passes through a specific area (the specific area is often in a state where it is difficult for the game ball to pass through), the game state is displayed regardless of the variable display device. It is decided to migrate.

That is, in the Pachislot machine 1, the game is started when the player bets the necessary medals and performs a start operation, whereas in the Pachinko machine, the game is started when the player operates the handle to fire the necessary game balls. Although they differ in that, for example, the game is started when the game ball passes through the starting area, they both have the same point that the game is started by the player's game action. Furthermore, the pachislot machine 1 and the pachinko machine have in common that the stop mode in which display is finally permitted (in other words, the content of the privilege to be granted) is determined when the start opportunity is established. .

In addition, in the pachislot machine 1, the variable display is basically stopped by the player's stop operation, whereas in the pachinko machine, the variable display is stopped by the satisfaction of the stop condition (not by the player's stop operation). Although they are different in that the variable display is stopped, they both have the same feature in that the variable display is stopped according to a predetermined result and a benefit is given according to the stopping mode. Furthermore, the pachi-slot machine 1 and the pachinko machine have in common that they can perform performances related to games. For example, the effect display device functions as the above-described effect display section or information display section. Furthermore, it goes without saying that the pachinko machine may also be provided with performance execution means such as the above-mentioned lamps, speakers, or other performance devices, and the performance may be performed using these.

Note that in many pachinko machines, decorative patterns (which may also be referred to as "identification information" or the like) are displayed in a variable manner in the effect display device. As mentioned above, the original game results are displayed on the variable display device, but the variable display device is configured to be small, and the display results are also displayed in a lighting pattern of a plurality of LEDs. Therefore, in many cases, it is difficult for players to recognize game results. For this reason, in most pachinko machines, the game is played by displaying decorative symbols in a variable manner (and in a static manner) on the effect display device in conjunction with the variable display of the variable display device. . In addition, such a fluctuating display of a decorative pattern may be performed (for production purposes, the fluctuating display may be started after a certain period of delay when a start opportunity is established, or may be temporarily stopped before a stop condition is met). Basically, similar to the above-mentioned variable table device, the identification information is displayed in a variable manner or in a stopped manner as the game progresses. ), and in the case of a miss, the decorative pattern is stopped and displayed in a non-special stopping mode (for example, a random pattern). Therefore, this is considered to be one mode of the variable display section mentioned above. It is also possible to apply the invention according to the embodiment.

That is, in this embodiment, the various items described as the configuration of the external structure or internal structure of the pachislot machine 1 are those that have characteristics unique to the pachislot machine 1 (for example, those that require medals and cannot be replaced with game balls, etc.) ) can be applied to the external structure or internal structure of a pachinko machine.

In addition, in pachinko machines, various controls related to games are performed by a main control circuit as a game control unit mounted on the main control board (partly, control related to payout is performed by a main control circuit that is electrically connected to the main control board). Various controls related to production are performed by a sub-control circuit as a production control section mounted on a sub-control board, so The various items described as the electrical configuration of the pachi-slot machine 1 can be applied as the electrical configuration of the pachinko machine, except for those that have characteristics unique to the pachi-slot machine 1 (for example, those related to stop operations).

In addition, in the pachi-slot machine 1, as described above, the gaming states that are relatively advantageous to the player (or may be disadvantageous depending on the configuration) include the bonus state, RT state, AT state, It is possible to provide an ART state or the like that combines these. For example, in the bonus state, by making the lottery mode of the minor role more advantageous than in the non-bonus state, it is possible to continue a state in which medals are easily awarded (increase) for a certain period of time, and in the RT state, the lottery mode of the minor role is made more advantageous than in the non-bonus state. By making the lottery mode more advantageous than the non-RT state, it is possible to maintain a state in which winnings are less likely to occur (as a result, medals are less likely to decrease), and in the AT state, the more advantageous stop operation mode is By being notified, it is possible to continue a state in which medals are more likely to be awarded (increase) for a certain period of time.

On the other hand, pachinko machines can also be provided with various game states having similar characteristics. For example, in a jackpot game state or a small win game state, the variable winning device is controlled differently than usual, so that the game ball can be changed to a state where it is easy to win, and thereby the game ball is awarded. This makes it possible to continue a state of easy (increasing) for a certain period of time. Also, for example, in a time-saving gaming state (sometimes referred to as an "electrical support state", etc.), a different control than usual is performed on the normal symbols to make it easier for the game ball to pass through the starting area. This makes it possible to increase the lottery frequency by the variable display device and to maintain a state in which the number of game balls is difficult to decrease for a certain period of time. Further, for example, in a variable probability game state, special symbols are controlled differently than usual, so that a state in which the probability of winning by the variable display device increases (as a result, the number of game balls is likely to increase) continues for a certain period of time. is possible.

That is, in this embodiment, various matters explained as the configuration of control regarding the transition (or transition) of the game state as the gameplay of the pachi-slot machine 1 are those that have characteristics unique to the pachi-slot machine 1 (for example, the It can be applied as a control configuration regarding the transition (or transition) of the gaming state of a pachinko machine, except for those that involve transition, etc.). Further, the same applies to various other matters described as the game performance of the pachi-slot machine 1.

Although this is a time-saving gaming state, pachinko machines can also shift to a time-saving gaming state when the number of games played during the non-time-saving gaming state (normal gaming state) reaches a specified number of times. There is. That is, even in a pachinko machine, if a ceiling function (unfavorable state (e.g., normal gaming state) continues for a predetermined period (e.g., 900 games (spins)) without shifting to an advantageous state (e.g., jackpot gaming state), The various matters described as the configuration of the ceiling function of the pachislot machine 1 are the configuration of the ceiling function of the pachinko machine. It can be applied as

In addition, although it is a time-saving gaming state, even in a pachinko machine, if the stop mode of the variable display device becomes a display result corresponding to a specific loss during a non-time-saving gaming state (normal gaming state), It is possible to use this as an opportunity to shift to a time-saving gaming state. In other words, even in pachinko machines, it is possible to transition (transition) the gaming state by displaying a specific display result (a specific combination of symbols) (not triggered by a transition to a jackpot gaming state, etc.). , the various matters described as a configuration regarding the transition (transition) of the RT state due to the display of a specific combination of symbols of the pachislot machine 1 are described as the configuration regarding the transition (transition) of the time-saving gaming state due to the display of a specific display result of the pachinko machine. Can be applied.

(Medalless gaming machine)
In the pachi-slot machine 1 of the present embodiment, the player's bet operation (that is, the operation of inserting the medals in hand into the medal slot 5 and placing a bet, or placing the credited medals on the MAX bet button 6a or 1 bet button) The game is started with one of the starting conditions being that there is an operation (operating 6b to place a bet), and if there is a payout of medals when the game ends, the hopper device 32 is driven and the medal payout port 11 is activated. Although the configuration of the pachi-slot machine 1 is not limited to this, the configuration of the pachi-slot machine 1 is not limited to this.

For example, this embodiment applies to all formats in which a player bets the gaming value necessary for a game, plays a game based on the bet, and is awarded a benefit (for example, a gaming value is awarded) based on the result of the game. It is possible to apply the invention according to the above. In other words, in addition to physically inserting (spending) and paying out medals through the player's actions, the game value held by the player is managed electromagnetically within the Pachislot machine 1 ( Alternatively, even if it is not electromagnetic, it is also possible to manage the game value in a manner that does not allow the player to directly contact the game value, and to enable games without medals. Here, such a pachi-slot machine 1 is referred to as a "medalless gaming machine." Note that medalless gaming machines are sometimes referred to as "managed gaming machines", "enclosed gaming machines", etc.

Note that it may be the main control circuit 100 (main control board 71) itself that electromagnetically manages the gaming value held by the player, or it may be the main control circuit 100 (main control board 71) that is attached to the main control circuit 100 (main control board 71). It may also be a (connected) gaming value management device (hereinafter, such a management device may be referred to as a "medal number control board"). An example in which this gaming value management device is provided will be explained below.

The gaming value management device is a device that includes at least ROM and RWM (or RAM) and is provided in the pachislot machine 1, and is a communication device (hereinafter, such a communication device will be referred to as a "connection terminal board"). It is connected to an external gaming value providing device (hereinafter, such a gaming value providing device may be referred to as a "communication-only unit") via an external gaming value providing device (such as a "communication-only unit") for two-way communication. The gaming value management device performs the gaming value lending operation (i.e., provides the gaming value necessary for the player to perform the gaming value betting operation) by performing the necessary communication with the external gaming value providing device. (i.e., the action of providing the player with the gaming value related to the award when the winning role is won (the winning combination is established), etc.); The player shall be able to perform actions such as electromagnetically recording the gaming value provided by the action. Note that the gaming value providing device is sometimes referred to as a "gaming value (gaming media) handling device," "gaming value (gaming media) lending device," or "sand."

In addition, the external gaming value providing device is connected to an external ball output management device (ball output management server), and the gaming value management device communicates with the external ball output management device through communication devices and external gaming value management devices. It is configured to be able to transmit ball release management information via the providing device. Here, the put-out ball management information is composed of various kinds of information necessary for an external ball-out management device to manage the put-out balls. Note that an example of the ball release management information will be described later. Furthermore, the external gaming value providing device and the external ball payout management device are connected, for example, via an Internet line.

Here, the term "balls paid out" directly means the number of gaming media paid out, but in this embodiment, for example, the term "balls paid out" refers to the difference number (net increase) obtained by subtracting the number of bets from the number paid out. The extent to which benefits are granted to players (for example, how much the player has gained (how much has the game store lost)) or how much has the player lost (how much has the game store gained The concept also includes the degree of continuation of an advantageous state (for example, a bonus state, an AT state, a series of advantageous sections, etc.), or the degree of gambling expected by a combination of these.

Further, for example, a possessed gaming value number display device (not shown) is provided on the front side of the Pachislot machine 1 to display the number of held gaming values, and the gaming value management device is configured to control the number of game values based on the management result of the number of gaming values held. The number of game values displayed on the held game value number display device of the lever may be managed. That is, the gaming value management device may be configured to not only record the total number of gaming values that a player can use for gaming using an electromagnetic method, but also to be able to control the display of the recorded results. . In this case, the gaming value management device has the ability to allow the player to freely transmit a signal indicating the number of recorded gaming values to the external gaming value providing device, and also allows the player to It has the ability to not reduce the number of recorded game values except when directly operated, and the signal indicating the number of recorded game values can only be transmitted through a communication device. is desirable.

Note that the gaming value management device not only has the function of electromagnetically managing the gaming value of a player using an external gaming value providing device, but also controls the number of gaming values bet based on the player's physical movements and the number of gaming values bet by the player's physical movements. The player may have a function of managing the number of game values paid out by the physical action of the player. That is, it may also be possible to manage the actual insertion and payout of medals in the conventional pachi-slot machine 1. In this way, the pachi-slot machine 1 can be controlled by a conventional method or by a method such as the medalless game machine described above, so no matter which specification the pachi-slot machine 1 has. Even if there is a common configuration, it is possible to have a common configuration. Further, in this case, it is possible to adopt a method in which the gaming value management device directly controls the above-mentioned selector 31 and hopper device 32, or these are controlled by the main control circuit 100 (main control board 71), It is also possible to adopt a method of indirect control by transmitting the control results.

In addition to the above, the pachi-slot machine 1 may be provided with various operating means necessary for operating the medalless gaming machine, such as a rental operating means and a return (payment) operating means, which can be operated by a player. In addition, the gaming value providing device includes various devices such as an input slot for valuables such as banknotes, an insertion slot for recording media (for example, an IC card), and a contactless communication antenna for depositing electronic money etc. from a mobile terminal. In addition, various operating means necessary for the operation of the medalless gaming machine, such as a loan operating means and a return operating means, which can be operated by a player may be provided (none of which are shown). Note that the insertable recording media include not only non-member recording media issued on the day at the gaming parlor, but also member recording media owned by members of the gaming parlor. The gaming value recorded on the non-member recording medium is valid only on that day (invalid after the next day), but the gaming value recorded on the member recording medium is valid even after the next day.

An example of the flow of the game in this case will be explained. For example, first, the player deposits value into the gaming value providing device using any method. The gaming value providing device subtracts a predetermined number of negotiable values in response to a player's operation on any of the lending operation means, and provides the pachi-slot machine 1 with a gaming value corresponding to the subtracted negotiable value. Then, the player plays the game, and repeats the above operations if more gaming value is required. Thereafter, when the player ends the game after acquiring a predetermined number of game values based on the result of the game, the player operates one of the return operation means. The gaming value management device transmits the number of gaming values to the gaming value providing device in response to the player's operation on any of the return operation means. The game value providing device discharges the recording medium on which the transmitted number of game values is recorded. The gaming value management device clears the number of gaming values stored in itself when transmitting the number of gaming values. The player can take the ejected recording medium to a prize exchange place or the like in order to exchange it for a prize, or the player can take the ejected recording medium to a gaming value providing device compatible with other Pachislot machines 1. By inserting it, you can move the machine and continue playing. Further, if the ejected recording medium is a member recording medium, it is valid even after the next day, so the game can be stopped at this point.

Note that in the above example, the game value management device transmits the total number of game values to the game value providing device in response to the player's return operation. It may be configured such that only the number of game values desired by the player can be transmitted. That is, the game value held by the player may be divided. In addition, the gaming value providing device records the transmitted gaming value number on a recording medium and outputs it, but it uses the above-mentioned non-contact communication antenna etc. to send the same value to the player's mobile terminal. For example, cash or cash equivalent may be sent as long as it provides the player with something of equal value.

In addition, the pachislot machine 1 or the gaming value providing device is provided with a lock operating means that can be operated by the player, and communication between the gaming value management device and the gaming value providing device is disabled depending on the operation of the lock operating means. It may be possible to control the state (locked state). In this case, in the Pachislot machine 1 or the gaming value providing device, for example, setting a PIN (and inputting the set PIN), issuing a one-time password (and inputting the issued one-time password), or biometric authentication. The lock state may be released when the result of the authentication process is normal.

According to the medalless gaming machine described so far, for example, some external structures such as the medal slot 5 and the medal payout slot 11, or the selector 31, etc. Since it is not necessary to provide some internal structures such as the hopper device 32, it is possible to reduce not only the cost and manufacturing cost of the game machine but also the power consumption of the game machine. Furthermore, since it becomes more difficult to access the inside of the gaming machine, fraudulent acts against the gaming machine can be prevented. Furthermore, since the player does not come into direct contact with the gaming media, the gaming environment can be improved and noise can be reduced. That is, it is possible to provide a gaming machine that can improve various environments surrounding the gaming machine.

(Example of configuration of medalless gaming machine)
Next, with reference to FIG. 34, a configuration example in which the pachi-slot machine 1 is configured as a medalless gaming machine will be described. FIG. 34 is a diagram showing an example of the configuration of a medalless gaming machine. Note that, below, a configuration example in which a medal number control board (gaming value management device) is provided will be mainly described.

As described above, the medal number control board is connected to the main control board 71 and manages the number of medals (number of gaming values) held by the player. Further, the medal number control board is connected to a communication dedicated unit (gaming value providing device) via a connection terminal board (communication device). Further, the medal number control board transmits ball payout management information to the ball payout management device via the connection terminal board and the communication dedicated unit. Further, a medal number control circuit (not shown) is mounted on the medal number control board. Further, the medal number control circuit includes, for example, a medal number control CPU (not shown), a medal number control ROM (not shown), and a medal number control RWM (not shown).

The ball output management device is, for example, a server for ball output management managed by an association (an information center) to which gaming machine manufacturers are members, and the transmitted ball output management information is stored in the ball output management device. This is provided for the purpose of making it possible to monitor whether the gambling performance of each gaming machine is appropriate (ball output performance).

Therefore, from this point of view, since the medal number control board and the connection terminal board play important functions in the pachislot machine 1 like the main control board 71, they should be designed in a manner that can prevent fraudulent acts and unauthorized modifications. It needs to be provided inside the pachi-slot machine 1. Configuration example 1 and configuration example 2 shown in FIG. 34 show examples of such aspects.

<Configuration example 1>
Configuration example 1 shown in FIG. 34 shows that the medal number control board and the connection terminal board are housed in the main control board case like the main control board 71. Here, the main control board case is usually subjected to various sealing treatments to make it difficult to open (or remove) or to make it possible to recognize traces of it being opened (or the number of times it has been opened). (For example, sealing by caulking, pasting of a seal seal, or pasting of a caulking sticker that records the cutting of the caulk, etc.)

Therefore, if the medal number control board and the connection terminal board are housed in the main control board case, the same security effect as the main control board 71 can be obtained, and fraudulent acts and unauthorized modification can be appropriately prevented.

<Configuration example 2>
In configuration example 2 shown in FIG. 34, unlike configuration example 1 described above, the medal number control board and the connection terminal board are housed in a medal number control board case provided separately from the main control board case. It shows that there is. The medal number control board case shall be configured as a transparent (or nearly transparent) resin case similar to the main control board case, and the medal number control board and connection terminals housed inside the case. The board shall be stored so that it is easily visible.

Here, the medal number control board case of configuration example 2 may be configured to undergo the same sealing process as the main control board case, or may be configured to undergo at least a part of the sealing process. You can also do that. For example, the medal number control board case may be sealed by caulking in the same way as the main control board case, but a sealing sticker may not be attached. Further, for example, in the main control board case, it is mandatory to use a predetermined caulking seal, but in the medal number control board case, any seal may be used as the caulking seal.

<Example of stored data>
The example of accumulated data shown in FIG. 34 shows an example of various data accumulated in the ball output management device. That is, the medal number control board shows an example of the ball output management information transmitted to the ball output management device via the connection terminal board and the communication dedicated unit. Note that this is just an example, and a configuration may be adopted in which some of the various information shown in FIG. 34 is not transmitted, or a configuration in which information other than the various information shown in FIG. 34 is transmitted. You can also do it.

Moreover, the timing at which the medal number control board transmits information to the communication-only unit is also arbitrary, and the timing at which the communication-only unit transmits information to the ball output management device is also arbitrary. The information may be transmitted at any timing as long as the ball output management device can monitor the ball output performance of each gaming machine on at least one unit (for example, one business day at a game parlor). . For example, the timing at which the medal number control board transmits information to the communication-only unit may be different from the timing at which the communication-only unit transmits information to the ball output management device. Further, for example, the timing at which the medal number control board transmits information to the communication dedicated unit may be different depending on the type of information.

The accumulated data "total number of coins inserted" is the cumulative number of coins inserted per unit after the power of each gaming machine is turned on. For example, the medal number control board transmits information on the number of game values bet by the player's bet operation to the communication dedicated unit at a predetermined timing (for example, every unit game), excluding the number bet by the replay operation. The communication dedicated unit transmits the cumulative total of the information to the ball payout management device at a predetermined timing (for example, at the end of business at the gaming parlor).

The accumulated data "total number of coins to be paid out" is the cumulative number of coins to be paid out per unit after the power of each gaming machine is turned on. For example, the medal number control board transmits information on the number of game values awarded through payout processing of a gaming machine, excluding those awarded through replay operations, to a communication dedicated unit at a predetermined timing (for example, every unit game). The communication dedicated unit transmits the cumulative total of the information to the ball payout management device at a predetermined timing (for example, at the end of business at the gaming parlor).

The accumulated data "MY" is the maximum number of difference in the number of coins that occurred during one unit after the power was turned on for each gaming machine (in short, the number of difference in the number of coins obtained during the period in which the gaming value increased the most in one unit. (referred to as "MY"). For example, the medal number control board calculates such a maximum difference in the number of medals, and transmits the calculated information to the communication-only unit at a predetermined timing (for example, at the end of business hours at the game parlor), and the communication-only unit transmits the information. is transmitted to the ball payout management device at a predetermined timing (for example, at the end of business at the gaming parlor).

The accumulated data "Total number of coins paid out for accessories" is the cumulative number of coins paid out per unit after the power of each gaming machine is turned on, and is the cumulative number of coins paid out during the operation of various accessory products. . For example, the medal number control board is dedicated to communication of information on the number of game values given by the payout process of the gaming machine during the operation of various accessories at a predetermined timing (for example, for each unit game during the operation of various accessories). The communication dedicated unit transmits the cumulative total of the information to the ball payout management device at a predetermined timing (for example, at the end of business at the game parlor).

The accumulated data "Total number of consecutive paid out coins" is the cumulative number of coins paid out per unit after the power of each gaming machine is turned on, and is the cumulative number of coins paid out per unit after the power of each gaming machine is turned on. This is the cumulative number of coins paid out during operation. For example, the medal number control board is dedicated to communication at a predetermined timing (for example, for each unit game during the operation of a continuous accessory) of information on the number of game values given by the payout process of a gaming machine during the operation of a continuous accessory. The communication dedicated unit transmits the cumulative total of the information to the ball payout management device at a predetermined timing (for example, at the end of business at the game parlor).

Further, the medal number control board transmits various information that can be displayed on the winning ratio monitoring device 54 to the communication-only unit at a predetermined timing (for example, at the time of calculation in the winning ratio monitoring device 54), and the communication-only unit The information is transmitted to the payout management device at a predetermined timing (for example, at the time of transmission from the medal number control board). In addition, the accumulated data "accessory object ratio" corresponds to the above-mentioned accessory ratio information, the accumulated data "continuous accessory ratio" corresponds to the above-mentioned continuous accessory ratio information, and the accumulated data "advantageous object ratio" corresponds to the above-mentioned continuous accessory ratio information, for example. For example, the "section ratio" corresponds to the above-mentioned specific section ratio information, and the accumulated data "instruction accessory ratio" corresponds to the above-mentioned accessory ratio information that is subject to aggregation and calculation even during the AT state. The accumulated data "status ratio of accessories, etc." corresponds to, for example, the above-mentioned specific section ratio information that is subject to aggregation and calculation even when various accessories are in operation.

The accumulated data "number of games" is the cumulative number of games played per unit after each gaming machine was powered on. For example, the medal number control board transmits information on the number of games played to a communication-only unit at a predetermined timing (for example, for each unit game), and the communication-only unit transmits the cumulative total of the information at a predetermined timing (for example, for each unit game). For example, the information is transmitted to the ball payout management device at the end of business hours at the game parlor.

The accumulated data "main control chip ID number" is an individual identification number (also referred to as "CPUID", also referred to as "chip ID number") of the main control circuit 100 of each gaming machine. For example, when the medal number control board sends various information to the communication-only unit, it sends information including this individual identification number, and when the communication-only unit sends various information to the ball output management device, it sends information including the individual identification number. Send information including this individual identification number.

The accumulated data "main control chip manufacturer code" is a manufacturer code recorded in the management area of the main ROM 102 of the main control circuit 100 of each gaming machine. For example, when the medal number control board sends various information to the communication-only unit, it sends information including this manufacturer code, and when the communication-only unit sends various information to the ball output management device, it sends this information including the manufacturer code. Send information including manufacturer code.

The accumulated data "main control chip product code" is a product code recorded in the management area of the main ROM 102 of the main control circuit 100 of each gaming machine. For example, when the medal number control board sends various information to the communication-only unit, it sends information including this product code, and when the communication-only unit sends various information to the ball output management device, it sends this information including the product code. Submit information including product code.

The accumulated data "medal number control chip ID number" is an individual identification number of the medal number control circuit of each gaming machine. For example, when the medal number control board sends various information to the communication-only unit, it sends information including this individual identification number, and when the communication-only unit sends various information to the ball output management device, it sends information including the individual identification number. Send information including this individual identification number. Note that if the main control board 71 is configured to send various information to the communication-only unit without providing a medal number control board, the information will be "0".

The accumulated data "medal number control chip maker code" is a maker code recorded in the management area of the medal number control ROM of the medal number control circuit of each gaming machine. For example, when the medal number control board sends various information to the communication-only unit, it sends information including this manufacturer code, and when the communication-only unit sends various information to the ball output management device, it sends this information including the manufacturer code. Send information including manufacturer code. Note that if the main control board 71 is configured to send various information to the communication-only unit without providing a medal number control board, the information will be "0".

The accumulated data "medal number control chip product code" is a product code recorded in the management area of the medal number control ROM of the medal number control circuit of each gaming machine. For example, when the medal number control board sends various information to the communication-only unit, it sends information including this product code, and when the communication-only unit sends various information to the ball output management device, it sends this information including the product code. Submit information including product code. Note that if the main control board 71 is configured to send various information to the communication-only unit without providing a medal number control board, the information will be "0".

In this way, the ball output management device is capable of accumulating various types of information (ball output management information) transmitted from gaming machines. Further, the ball output management information includes a plurality of individual identification information (for example, the above-mentioned "main control chip ID number" to "medal number control chip product code") that can identify individual gaming machines. Therefore, the ball output management device can identify the gaming machine that is the sender based on these pieces of individual identification information, and also, for example, from a certain point on, the "main control chip ID number" and "medal number control chip ID number" If the correspondence relationships between the two control boards become different, it is possible to recognize the possibility that one of the control boards has been replaced (that is, the possibility that fraudulent activity or unauthorized modification has been carried out).

Further, the ball output management information includes a plurality of pieces of ball output information (for example, the above-mentioned "total number of inserted coins" to "number of games played") that can identify the ball output performance per unit. Therefore, the ball output management device can recognize whether the gambling quality of the sending gaming machine is within an appropriate range based on the ball output information. For example, if the ``total number of coins paid out'' or ``instruction included accessory ratio'' becomes extremely high after a certain point, there is a possibility that fraudulent activity or unauthorized modification has been carried out, or there is some flaw in the original specification design. It is possible to recognize the possibility that something has happened.

If the above-mentioned possibility is recognized by the ball payout management device, the result will be notified to the game parlor or the game machine manufacturer, and it can be expected that appropriate measures will be taken. In other words, a plurality of managed gaming machines, a gaming value providing device (a communication dedicated unit) that transmits the ball output management information transmitted from the managed gaming machines to the ball output management device, and each By constructing a management system that includes a ball output management device that manages the ball output performance of the managed gaming machines, it is possible to appropriately manage all managed gaming machines under management.

<Modification 1>
As described above, the medalless gaming machine can be configured so that the number of gaming values held by the player is managed by the medal number control board. Therefore, the medal number control board may be provided with a medal number monitoring device (not shown) so that the manager of the game parlor can grasp such management status or other information.

The medal number monitoring device is composed of, for example, a four-digit, seven-segment LED, and is provided inside the medal number control board case. The medal number monitoring device collects and calculates various types of information (for example, part or all of the above-mentioned ball output management information) regarding the number of gaming values aggregated and calculated by the medal number control CPU (or may be the main CPU 101). Display sequentially. Incidentally, if all the display contents of the winning ratio monitoring device 54 are displayed by the medal number monitoring device, the winning ratio monitoring device 54 may not be provided. Alternatively, the role ratio monitor device 54 may also be used as a medal number monitor device.

Further, the medal number monitoring device may be mounted on the medal number control board, or may be mounted on another board (for example, a connection terminal board) connected to the medal number control board. Good too. Further, as long as it is within the cabinet G, it may be provided at another location. For example, it may be provided on the medal number control board case. Furthermore, a management switch for starting the display on the medal number monitoring device or for switching its contents may be provided in the cabinet G, and various information may be displayed when this switch is operated. Furthermore, on the premise that such a management switch is used, the information display device 14 may also be used as a medal number monitoring device, for example.

Note that the medal number monitoring device may display the type of error state that has occurred when various error states related to itself occur. For example, if a communication error occurs with the main control board 71, a communication error with the connection terminal board, a communication error with the gaming value providing device, or an abnormality occurs in the medal number control RWM. In certain cases, a corresponding numerical value may be displayed. In this case, in order for the game parlor manager to easily recognize which error condition the displayed value corresponds to, the corresponding relationship is displayed on or near the medal number control board case. What is necessary is to provide an explanatory section (such as pasting a sticker or printing) to show the information.

<Modification 2>
As described above, in the medalless gaming machine, the medal number control board can be configured to transmit ball output management information to the outside via the connection terminal board. In this embodiment, an external centralized terminal board 55 is additionally provided for transmitting information to the outside. Therefore, the connection terminal board and the external centralized terminal board 55 can be configured as follows, for example.

For example, the connection terminal board and the external centralized terminal board 55 are configured as a common terminal board. This not only makes it possible to reduce the number of parts, but also reduces wiring directed to the outside, thereby increasing the security effect.

Further, for example, the connection terminal board and the external centralized terminal board 55 are configured as one unit. Further, for example, the connection terminal board and the external centralized terminal board 55 are arranged close to each other at least in the cabinet G. Thereby, work efficiency during connection can be improved. Further, since the length of the wiring can be made constant and the wiring locations can be limited, the security effect can be enhanced.

<Modification 3>
As described above, the medalless gaming machine can be configured so that the ball payout management information is transmitted to the ball payout management device. Further, the ball output management device can appropriately manage the ball output performance of each medalless gaming machine based on the transmitted ball output management information. Therefore, on the premise that the ball dispensing performance can be appropriately managed in this manner, the above-described limiter may not be provided. That is, it may not have a function of forcibly ending the advantageous section based on the establishment of a certain restriction condition.

Alternatively, the medal number control board may be provided with a function to appropriately manage the ball output performance, and on the premise that the ball output performance can be appropriately managed in this way, the above-mentioned limiter may not be provided. . That is, it may not have a function of forcibly ending the advantageous section based on the establishment of a certain restriction condition.

For example, the medal number control board is configured to include a payout monitoring RWM (which may be the above-mentioned medal number control RWM or another RWM). The ball payout monitoring RWM is initialized, for example, when the setting is changed, but monitors the ball payout in such a way that it is not initialized when the advantageous section ends. If the monitored ball output exceeds a certain threshold, for example, the advantageous section itself will not be forcibly terminated, but the probability of navigation occurrence will be reduced, the probability that the AT state will be extended, etc. Alternatively, the AT state itself may be terminated to reduce the ball dispensing performance. Even in this case, it becomes possible to appropriately manage the ball dispensing performance. In addition, in this case, such a control result may be transmitted to the ball release management device as ball release management information. That is, a configuration may be adopted in which both the medal number control board and the ball output management device can manage the ball output performance of each medalless gaming machine.

(Example of configuration of main control board of pachislot machine)
Next, with reference to FIG. 35, a configuration example of the main control board 71 of the pachi-slot machine 1 will be described. FIG. 35 is a diagram showing an example of the configuration of the main control board 71. Note that, below, a configuration example for reusing the main control board 71 will be mainly described.

As mentioned above, in the Pachislot machine 1, there are various restrictions on the specifications of the main control board 71, one of which is that the manufacturer's name and board management number must be printed on the main control board 71. It has become. The manufacturer name is the name of the gaming machine manufacturer that manufactures the pachi-slot machine 1, and the management number is a number for identifying the model of the main control board 71.

<Configuration example 1>
Configuration example 1 shown in FIG. 35 shows that the manufacturer's name and board management number are printed in letters on the main control board 71 as in the conventional case. Here, in configuration example 1 shown in FIG. 35, first, it is assumed that a pachi-slot machine 1 (hereinafter described as "model A") on which the main control board 71 is mounted is manufactured by BB Corporation. At this time, initially, only the manufacturer name "BB Co., Ltd." and the board management number "BB-00-11-22" at the bottom are printed. Thereafter, if Model A is removed from the game parlor and, for example, AA Co., Ltd. attempts to reuse the main control board 71 to manufacture a different Pachislot machine 1 (hereinafter referred to as "Model B"), then AA Co., Ltd. AA laser-engraved the manufacturer's name and board management number printed on the lower row, and in a different space wrote the manufacturer's manufacturing number and board management number related to the company (for example, the manufacturer's name and board management number on the upper row of configuration example 1 shown in Figure 35). The name "AA Co., Ltd." and the board control number "AA-00-11-22" must be newly printed.

Then, after that, model B is removed from the game parlor, and if, for example, BB Co., Ltd. attempts to reuse the main control board 71 to manufacture a different pachislot machine 1 (hereinafter described as "model C"). In this case, BB Co., Ltd. would have to use laser engraving to delete the manufacturer's name and board management number that had been printed on the top row, and then print a new manufacturing number and board management number related to the company in a different space. However, in configuration example 1 shown in FIG. 35, there is no more free space, so even though reuse is still possible in terms of hardware, it is difficult to reuse the main control board 71 due to the above-mentioned restrictions. The problem was that sometimes it was not possible.

Note that this also applies even if multiple manufacturer names and board management numbers are printed from the beginning. For example, even if the serial number and board management number for both AA Corporation and BB Corporation are printed in advance, the serial number and board management number for AA Corporation are laser engraved at the time of manufacturing model A. This is because it will be deleted. Therefore, although BB Co., Ltd. may be able to reuse the product, AA Co., Ltd. may not be able to reuse it. On the other hand, the following configuration examples 2 and 3 can be expected to solve the above-mentioned problems. That is, it is possible to improve the reusability of a board used for controlling a game, such as the main control board 71.

<Configuration example 2>
Configuration example 2 shown in FIG. 35 shows printing of a code including the manufacturer's name and board management number. Note that in configuration example 2 shown in FIG. 35, a QR code (registered trademark), which is a two-dimensional code, is used as an example of a code including the manufacturer's name and board management number, but JAN code (bar code) and other The following code can be used. In other words, the code can be any type of code as long as it contains information that allows the confirming person to uniquely identify the manufacturer name and board control number by some means (e.g., mobile terminal, etc.). Good too.

In configuration example 2 shown in FIG. 35, first, when it is assumed that model A is manufactured by BB Corporation, the first code from the right is printed. The first code from the right includes information that can identify the serial number and board management number related to BB Corporation. Afterwards, when Model A is removed from the game parlor and AA Corporation attempts to manufacture Model B, the second code from the right is printed and the first code from the right is deleted by laser engraving. The second code from the right includes information that can identify the serial number and board management number related to AA Corporation.

Afterwards, when Model B is removed from the game parlor and BB Co., Ltd. attempts to manufacture Model C, the third code from the right is printed and the second code from the right is deleted by laser engraving. The third code from the right includes information that can identify the serial number and board management number related to BB Corporation. After that, even if model C was removed from the game parlor and AA Co., Ltd. tried to reuse the main control board 71 to manufacture a different pachislot machine 1, AA Co., Ltd. The code is removed by laser engraving, and the fourth code from the right is printed, so that the fourth code from the right includes information that can identify the serial number and board control number related to AA Co., Ltd. For example, it becomes possible to reuse the main control board 71 in a new pachi-slot machine 1.

That is, in configuration example 2 shown in FIG. ) Since space can be saved, it is possible to improve reusability compared to configuration example 1 shown in FIG. 35.

<Configuration example 3>
Configuration example 3 shown in FIG. 35, like configuration example 2 described above, shows that a code including the manufacturer's name and board management number is printed. Note that in configuration example 3 shown in FIG. 35, a plurality of (for example, four) codes are printed from the beginning. For example, assume that two copies of AA Corporation and BB Corporation are printed. In addition, the code can be read by caulking the parts corresponding to each code on the surface of the main control board 71 (or on the corresponding main control board case) with, for example, a belt-shaped member. It is possible to be fixed in an impossible state. Furthermore, for example, by cutting the band-like member or the like, it is possible to release the fixation and make the code readable.

In configuration example 3 shown in FIG. 35, first, when it is assumed that model A is manufactured by BB Corporation, only the first code from the right is readable, and the second to fourth codes from the right are readable. is considered unreadable. The first code from the right includes information that can identify the serial number and board management number related to BB Corporation. After that, model A was removed from the game parlor, and for example, when AA Co., Ltd. tried to manufacture model B, only the second code from the right was readable, and the first, third, and fourth codes from the right were readable. The second code is rendered unreadable. The second code from the right includes information that can identify the serial number and board management number related to AA Corporation.

After that, Model B was removed from the game parlor, and for example, when BB Co., Ltd. tried to manufacture Model C, only the third code from the right was readable, and the first, second, and fourth codes from the right were readable. The second code is rendered unreadable. The third code from the right includes information that can identify the serial number and board management number related to BB Corporation. After that, even if model C was removed from the game parlor and AA Co., Ltd. tried to reuse the main control board 71 to manufacture a different pachislot machine 1, AA Co., Ltd. By making only the code readable and making the first to third codes from the right unreadable, it becomes possible to reuse the main control board 71 in a new pachi-slot machine 1.

In addition, in configuration example 3 shown in FIG. 35, it is sufficient to make at least one code readable and the other codes unreadable, so further reuse is possible and more It is also possible to reuse it at other gaming machine manufacturers. In addition, in the configuration example 3 shown in FIG. 35, it is also possible to provide only the caulking holes and print a code at the location corresponding to the caulking hole each time the product is reused.

[10. Second gaming machine]
Next, with reference to FIGS. 36 to 120, another specific example of the specifications regarding the gaming performance of the pachi-slot machine 400 will be described as a "second gaming machine". Note that the second gaming machine will be described below as a pachi-slot machine exclusively for 3BET. That is, in the second gaming machine, the start lever 7 and the start switch 7S can detect a start operation when three medals are bet.

[Structure of Pachislot machine]
First, with reference to FIG. 36, the structure of the pachi-slot machine 400, which is the second gaming machine, will be explained. Note that FIG. 36 is a diagram showing the external structure of the pachi-slot machine 400.

[Case]
The housing 500 of the pachi-slot machine 400 shown in FIG. It has a lower door mechanism DD2 disposed at the lower front surface of the lower door mechanism. Since the cabinet G and the upper door mechanism UD are the same as those of the above-mentioned pachi-slot machine 1 (see FIG. 1), their explanation will be omitted.

The lower door mechanism DD2 has a main display window 4 provided approximately at the center of its upper part, and a reel unit RU2 attached to the inside of the cabinet G on the back side of the main display window 4. There is.

The reel unit RU2 is mainly composed of four reels 3A (first reel), 3B (second reel), 3C (third reel), and 3D (fourth reel). Each of the reels 3A, 3B, 3C, and 3D is composed of, for example, a cylindrical reel body and a translucent reel band attached to the circumferential surface of the reel body. , 20) symbols are drawn at predetermined intervals along the rotation direction of the reels. Further, the reels 3A, 3B, 3C, and 3D are arranged in parallel (in a horizontal row) so that each reel can rotate at a constant speed in the vertical direction. The main display window 4 is configured as a transparent panel made of resin, for example, and allows at least some (for example, three) of the symbols on the circumferential surface of each reel 3A, 3B, 3C, and 3D to be visually recognized. Furthermore, inside each reel 3A, 3B, 3C, and 3D, a light source (a reel lamp included in lamps and LEDs to be described later) is provided at least at a position where the symbols can be seen from the main display window 4. When 3A, 3B, 3C, and 3D are rotating, they are illuminated from inside with a constant brightness to ensure the visibility of the symbols.

Further, the lower door mechanism DD has four stop buttons 8A, 8B, 8C, and 8D provided substantially in the center below the pedestal. Each stop button 8A, 8B, 8C, 8D is provided corresponding to each reel 3A, 3B, 3C, 3D, and is an operation section that accepts a player's gaming operation (stop operation) to stop the rotation of each reel. be.

Sub performance display section 22, performance button 10b, MAX bet button 6a, 1 bet button 6b, settlement button 9, performance button 10a, medal slot 5, information display device 14, start lever 7, locking mechanism 15, waist panel 13, the medal receiving tray 12, the medal payout opening 11, and the sound-transmitting holes 24a and 24b are the same as those in the above-mentioned pachi-slot machine 1 (see FIG. 1), and therefore their explanation will be omitted.

In this embodiment, the upper door mechanism UD and the lower door mechanism DD2 are provided in response to the fact that the inside of the cabinet G is partitioned into an upper space and a lower space. As long as it can be opened and closed, it can be constructed as a single door mechanism or as three or more door mechanisms. Moreover, it can also be configured as a double door mechanism (for example, an outer door and an inner door) in the front-rear direction. Further, the upper door mechanism UD and the lower door mechanism DD2 can also be simply referred to as a "door" or "door", and since they function as members that can open and close the opening in the cabinet G, they can be referred to as "opening/closing members" or "doors". It can also be referred to as a "door member" or a "door member."

[Variable display section]
Each reel 3A, 3B, 3C, 3D is rotated by driving and controlling stepping motors 51A, 51B, 51C, 51D, which will be described later, when the start lever 7 is operated (starting operation is performed by the player). Start. As a result, the symbols displayed on the main display window 4 are displayed in a variable manner. In addition, when each stop button 8A, 8B, 8C, 8D is operated (when a stop operation is performed by the player), each reel 3A, 3B, 3C, 3D is operated by a stepping motor 51A, 51B, 51C, which will be described later. Each rotation is stopped by drive control of 51D. As a result, the symbols displayed on the main display window 4 are stopped and displayed.

That is, each reel 3A, 3B, 3C, 3D and the main display window 4 have a variable display section (means) that can variably display (and stop display) a plurality of symbols in a plurality of rows, or a variable display section (means) that can variably display (and stop display) a plurality of symbols in a plurality of rows. A plurality of variable display units (means) capable of static display are configured. Note that the variable display section (means) can also be referred to as a "symbol display section (means)", a "variable display section (means)", etc. Further, the symbols can be referred to as "pictures", "patterns", etc., and can also be referred to as "identification information" in that sense, since any information that can be visually identified by the player is sufficient.

Further, the main display window 4 is configured so that when the rotation of each reel 3A, 3B, 3C, and 3D is stopped, three consecutively arranged symbols for each reel are displayed within its frame. There is. That is, the main display window 4 displays one symbol in each of the upper, middle, and lower regions of each column (three in total) (within the frame of the main display window 4, there are 3 rows x 4 columns (The design is displayed in this manner.) Note that the main display window 4 is sometimes referred to as a "symbol display area" or a "window section."

Furthermore, an effective line is defined in the main display window 4. The active line is a line for determining whether or not a prescribed combination of symbols has been displayed when symbols in all rows have been stopped and displayed in response to a stop operation by the player. In this sense, the active line can also be referred to as a "winning line", a "judgment line", etc. Further, the effective line is configured as a line that connects any one of the regions in each column. That is, when the main display window 4 is configured to display symbols in a manner of 3 rows x 4 columns, it is possible to define a maximum of 81 valid lines. However, in reality, one or more of the lines can be defined as valid lines, and the other lines can be defined as invalid lines that are not valid lines. In the second gaming machine, the active line is a line connecting the middle area of the first reel 3A, the middle area of the second reel 3B, the middle area of the third reel 3C, and the lower area of the fourth reel 3D. - middle - lower) only.

In addition, in order for the active line to be activated, the medals required for the current game (the number of medals available for starting the game) must be bet before the player starts the operation. The number of active lines displayed may be the same regardless of the number of bets, or may vary depending on the number of bets.

In addition, in this embodiment, the variable display section has four reels 3A, 3B, 3C, and 3D and a main display window 4 that can display three symbols in each column, so that three rows can be displayed. Although the symbols are displayed in the form of ×4 columns, the pattern display manner in the variable display section is not limited to this. For example, by setting the number of reels to 1, 2, 3, or 5 or more, and by setting the number of symbols displayed in each row to 1, 2, or 4 or more, the above-mentioned aspect can be achieved. It is also possible to display the designs in different ways. Furthermore, in this case, the number of definable effective lines is also increased or decreased as appropriate.

Further, in the present embodiment, the variable display section displays symbols in a variable manner by rotating each reel 3A, 3B, 3C, and 3D, but the configuration of the variable display section is not limited to this. For example, the configuration may use an image display device similar to the main display device 210 and the sub display device 220, or the configuration may use another display device (for example, an organic EL or 7-segment LED). Alternatively, for example, a configuration using other physical devices (eg, a belt, etc.) may be used. Further, the arrangement, size, etc. of the variable display section can be changed as appropriate.

Further, in this embodiment, the variable display section functions as a main side display section directly related to the game, which is controlled by the main control circuit 100 described below. A variable display section may be provided as a sub-display section that is controlled by a sub-display section that is related to performances that are not directly related to games. Note that the sub-side display section can be configured using, for example, the main display device 210 and the sub-display device 220. In other words, a variable display section that displays symbols in a variable manner in response to a player's start operation (or other start conditions are met), and that stops and displays symbols in response to a player's stop operation (or other stop conditions are met). In addition to the main side display section, a sub side display section may also be provided. In this case, in order for the player to be able to identify whether the variable display section is directly related to the game or not, the words "Kyokudou" or "Main Reel" are displayed near the main side display section. It is sufficient to attach an identification display in which is displayed to make it possible to identify that the variable display section is the main display section. Note that such an identification display may be displayed on the main display device 210 or the sub display device 220.

[Stop button]
As described above, the pachi-slot machine 400 has stop buttons 8A, 8B, 8C, and 8D provided corresponding to the respective reels 3A, 3B, 3C, and 3D, and accepting a stop operation by a player to stop the rotation of each reel. Equipped with Further, such a start operation is detected by a stop switch 8S, which will be described later. Therefore, each stop button 8A, 8B, 8C, 8D and stop switch 8S constitute a stop operation detection section (means) capable of detecting a stop operation by a player. Note that the stop button only needs to be able to detect the player's stop operation, and its shape, arrangement, size, etc. can be changed as appropriate.

[Electrical configuration of pachislot machine]
Next, with reference to FIG. 37, the electrical configuration of pachi-slot machine 400 will be described. Note that FIG. 37 is a block diagram showing the electrical configuration of the pachi-slot machine 400.

As described above, the pachi-slot machine 400 includes a main control board 71, a sub-control board 72, a main relay board 73, and a sub-relay board 74. The main control board 71, the sub-control board 72, the main relay board 73, and the sub-relay board 74 are the same as those in the above-mentioned pachi-slot machine 1 (see FIG. 1), and therefore their description will be omitted.

The main control board 71 includes stepping motors 51A, 51B, 51C, 51D, a setting key type switch 52, a reset switch 53, a role ratio monitor device 54, an external centralized terminal board 55, a hopper device 32, and a medal auxiliary storage switch 33S. , a power supply device 34 is electrically connected. In addition, the main control board 71 is electrically connected to the door opening/closing monitoring switch 56, medal sensor 31S, bet switch 6S, start switch 7S, stop switch 8S, payment switch 9S, and information display device 14 via the main relay board 73. It is connected to the. Note that, if the first interface board 301 for a test machine and the second interface board 302 for a test machine are mounted, they are electrically connected to the main control board 71 via the main relay board 73, for example.

Stepping motors 51A, 51B, 51C, and 51D are connected to each reel 3A, 3B, 3C, and 3D via gears each having a predetermined reduction ratio, and rotate each reel 3A, 3B, 3C, and 3D by driving the stepping motors 51A, 51B, 51C, and 51D. and stop it. Note that each reel 3A, 3B, 3C, and 3D rotates at a fixed angle each time one pulse is output to each stepping motor 51A, 51B, 51C, and 51D. The number of times pulses are output to the stepping motors 51A, 51B, 51C, and 51D is counted, and the symbol positions on each reel 3A, 3B, 3C, and 3D are managed based on the count results. Furthermore, each reel 3A, 3B, 3C, and 3D has a reel index (not shown) that determines the initial position for such management, and an index sensor (not shown) that detects the position of the reel index. provided.

[Second gaming machine]
Next, with reference to FIGS. 38 to 120, a specific example of the specifications regarding the gaming performance of the pachi-slot machine 400 will be described as a "second gaming machine". It should be noted that some or all of the various specifications and functions described as the second gaming machine in this embodiment can be applied to the other gaming machines described in this embodiment, and Some or all of the various specifications and functions described as another gaming machine in this embodiment can be applied to the first gaming machine in this embodiment. That is, the invention according to this embodiment can be a combination of these as appropriate.

The second gaming machine has a non-bonus state and a bonus state as gaming states. In addition, the non-bonus state includes the RB flag state where "RB" (regular bonus) described below is carried over, the BB flag state where "BB" (big bonus) described below is carried over, and any bonus. It is composed of non-flag players that have not won any winning combinations (have not been carried over). Note that the non-flag period is in the normal state. In addition, the bonus state is an RB operating state that changes in response to a symbol combination related to "RB" being displayed, and a BB operating state that shifts in response to a symbol combination related to "BB" being displayed. It consists of:

Furthermore, in the second gaming machine, it is possible to play a game with three medals bet (3 medal bet state). Note that "bet" means that the player inserts three medals into the medal slot 5 to play the game, and that the player operates the MAX bet button 6a or 1 bet button 6b to withdraw from the credits. This includes both the placing of three medals and the automatic placing of three medals as a result of winning a replay combination.

[RT state transition]
Next, with reference to FIG. 38, the transition of the RT state in the second gaming machine will be explained. FIG. 38 is a diagram for explaining the transition of the RT state in the second gaming machine.

As shown in FIG. 38, the second gaming machine provides four types of RT states, RT0 state to RT3 state, in which the types of replay internal winning combinations and their winning probabilities are different from each other. The RT state is set to the RT0 state when initialization is performed by a setting change operation, when other initialization conditions are satisfied, or at the time of factory shipment.

The second gaming machine is provided with a first-class special bonus (RB) and a bonus continuous operating device (BB) related to the first-class special bonus as bonus prizes. The RB operating state is a gaming state that ends when a predetermined number of wins (for example, the upper limit is 8) or a predetermined number of games (for example, the upper limit is 12) are played. Constructed as. The BB operating state is configured as a gaming state that ends when a predetermined number of medals is paid out (for example, the upper limit is 55). Further, in the BB operating state, the RB is configured to automatically operate, and is controlled so that the RB is always in operation while the BB is operating. Note that although the second gaming machine is provided with a BB and an RB, only the RB may be provided.

In the RT0 state, when "RB" is won and the state is between RB flags, the RT state shifts from the RT0 state to the RT2 state. In the RT2 state and in the advantageous section described below, the main display device 210 and the instruction monitor notify the stop operation mode (for example, push order navigation, etc.) to avoid displaying the combination of symbols related to "RB". conduct. In addition, in the RT0 state, if the player wins "BB" and enters the BB flag state, the RT0 state shifts to the RT2 state. In the state between BB flags, no lottery is performed regarding the balls to be played (same as the "balls to be played" described in the first gaming machine). In the normal state, if you win "BB", the main display device 210 will display "Preparing" or "Waiting" until the BB starts and ends and the state shifts to the state between RB flags, and when the state shifts to the state between RB flags. , terminate the preparation or standby display.

When a combination of symbols related to "RB" is displayed and the RB operating state is entered, the RT state shifts from the RT2 state to the RT3 state. Further, when a combination of symbols related to "BB" is displayed and the state shifts to the BB operating state, the RT state shifts from the RT2 state to the RT3 state.

When the RB working state or the BB working state ends, the normal state is entered, and the RT state shifts from the RT2 state to the RT1 state. Thereafter, the transition to the RT0 state does not occur until initialization is performed by a setting change operation or other initialization conditions are satisfied. That is, in the RT1 state, when "RB" is won and the state is between RB flags, the RT state shifts from the RT1 state to the RT2 state. In addition, in the RT1 state, if the player wins "BB" and enters the BB flag state, the RT1 state shifts to the RT2 state.

In addition, when initializing by setting change operation, it is determined whether to clear all data in the designated storage area or to clear a part of the gaming state, depending on the gaming state and the on/off state of the reset switch 53. You may also do so. Further, when the power is turned on with the setting key type switch 52 and the reset switch 53 in the on state, all data may be cleared regardless of the gaming state. Further, when the power is turned on with the setting key type switch 52 in the on state and the reset switch 53 in the off state, the RB carryover flag may not be initialized if the RB flag state is between. Further, if the state is between BB flags, all data including the BB carryover flag may be cleared.

[Symbol arrangement configuration of second gaming machine]
Next, with reference to FIG. 39, the symbol arrangement of the second gaming machine will be described. FIG. 39 is a diagram showing an example of a symbol arrangement table of the second gaming machine. As shown in FIG. 40, in the second gaming machine, "Red 7", "BAR", "Replay", "Bell", "Scroll", "Cherry", "Blank 1", "Blank 2", " Ten types of symbols, ``Upper Symbol'' and ``Lower Symbol,'' are arranged at the positions shown in FIG. 39 on each reel 3A, 3B, 3C, and 3D. Further, as shown in the symbol code table, symbol codes 1 to 10 are assigned to each symbol.

[Internal winning combination configuration of second gaming machine]
Next, the internal winning combination configuration of the second gaming machine will be explained with reference to FIGS. 40 to 49. 40 and 41 are diagrams showing an example of an internal lottery table of the second gaming machine. Further, FIGS. 42 and 43 are diagrams showing an example of a symbol combination table of the second gaming machine. Further, FIGS. 44 to 49 are diagrams showing an example of the correspondence between the internal winning combination, the stop operation mode, the display combination, etc. of the second gaming machine. That is, in the following, which symbol is selected depending on the type of internal winning combination drawn in the second gaming machine and the stop operation mode (i.e., batting order, stop operation timing, etc.) when each internal winning combination is won. We will explain whether the combinations (which can also be referred to as display combinations, winning combinations, stop display modes, display results, etc.) are displayed.

First, in the second gaming machine, in the internal lottery process, each internal winning combination shown in FIGS. 40 and 41 is won with the probability (lottery value/probability denominator: 65536) shown in FIGS. 40 and 41. The symbol combinations that are permitted to be displayed when each internal winning combination is won are as shown in "corresponding symbol combinations" in FIGS. 40 and 41. In addition, in FIGS. 42 and 43, "RB" and "BB" shown in "Contents" indicate a combination of symbols related to a bonus role, "RP" indicates a combination of symbols related to a replay role, and "NM" indicates a combination of symbols related to small roles.

“F_Normal Reply 1” is configured to be determined as an internal winning combination in non-bonus states (RT0, RT1, RB inside (RB between flags state), BB inside (between BB flags state)). As shown in FIGS. 44, 46, and 48, when "F_Normal Rep1" is determined as the internal winning combination, if the first stop operation is the first reel 3A (reel A), "RP01" ( CL reply) or "RP04" (XU reply) will be displayed, and a replay will be granted. Also, if the first stop operation is the second reel 3B (reel B), the third reel 3C (reel C), or the fourth reel 3D (reel D), "RP02" (TL rep), "RP03" ( Either TL reply), [RP05] (XD reply), or "RP06" (XD reply) will be displayed, and a replay will be granted.

"RP01" displays "replay" symbols in a straight line in the middle row on the first reel 3A to third reel 3C, so it can be called "middle row rep (CL rep)." Furthermore, since "RP04" displays the "replay" symbols upward to the right on the first reel 3A to third reel 3C, this can be referred to as a "replay upward to the right (XU replay)". "RP02" and "RP03" display "Replay" symbols in a straight line at the top on the first reel 3A to third reel 3C, so they can be collectively referred to as "upper stage rep (TL rep)". can. [RP05] and "RP06" display the "replay" symbol downward to the right on the first reel 3A to third reel 3C, so they are collectively referred to as "downward right rep (XD rep)". I can do it.

“F_Normal Reply 2” is configured to be determined as an internal winning combination in a non-bonus state. As shown in FIGS. 44, 46, and 48, when "F_Normal Rip 2" is determined as the internal winning combination, if the first stop operation is reel A, "RP01" (CL Rip) is displayed. , replay will be granted. Also, if the first stop operation is reel B, reel C, or reel D, "RP02" (TL rep), "RP03" (TL rep), [RP05] (XD rep), "RP06" (XD rep) ) will be displayed and a replay will be granted.

“F_Normal Reply 3” is configured to be determined as an internal winning combination in a non-bonus state. As shown in FIGS. 44, 46, and 48, when "F_Normal Rip 3" is determined as the internal winning combination, if the first stop operation is reel A, "RP01" (CL Rip) is displayed. , replay will be granted. Further, if the first stop operation is reel B, reel C, or reel D, either "RP02" (TL reply) or "RP03" (TL reply) is displayed, and a replay is awarded.

“1 out of F_RB” is configured to be determined as an internal winning combination in the bonus state (RB operating state and BB operating state). In the bonus state, if "1 out of F_RB" is determined as the internal winning combination, one of "NM30" to "NM80" will be displayed regardless of the stop operation mode, and one medal will be paid out. Ru.

“F_RB Medium Bell” is configured to be determined as an internal winning combination in the bonus state. In the bonus state, if "F_RB Medium Bell" is determined as the internal winning combination, one of "NM01" to "NM29" will be displayed regardless of the stop operation mode, and 15 medals will be paid out. .

“F_Common Bell” is configured to be determined as an internal winning combination in a non-bonus state. As shown in FIG. 44, FIG. 46, and FIG. 48, when "F_Common Bell" is determined as the internal winning combination, any one of "NM13" to "NM15" is displayed regardless of the stop operation mode, and 15 coins are displayed. medals will be paid out.

“F_batting order bell 01” to “F_batting order bell 24” are configured to be determined as internal winning combinations in a non-bonus state. As shown in FIGS. 44, 46, and 48, "F_batting order bell 01" to "F_batting order bell 24" have 24 options (24 If any one of the batting orders is the correct pressing order), and it is determined as an internal winning combination, if the stop operation is performed in the corresponding correct pressing order. , one of "NM01" to "NM12" is displayed, and 15 medals are paid out. On the other hand, if the stop operation is not performed in the corresponding correct pressing order, one of "NM30" to "NM58" is displayed and one medal is paid out. For example, if "F_batting order Bell 01" is determined as the internal winning combination, if the first stop operation is reel A, the second stop operation is reel B, and the third stop operation is reel C, the correct pressing order will be, "NM01" (C_12 bells) is displayed, and 15 medals are paid out. On the other hand, if the first stop operation is not reel A, the second stop operation is not reel B, and the third stop operation is not reel C, either "NM30" (S_batting order mistake 01) or "NM34" (S_batting order mistake 03) is displayed, and one medal is paid out.

“F_Middle Che 1” is configured to be determined as an internal winning combination in a non-bonus state. As shown in FIG. 44, FIG. 46, and FIG. 48, when “F_middle check 1” is determined as the internal winning combination, if the first stop operation is reel A or reel D, “NM17” (S_middle check 1), "NM18" (S_Middle Che 2) is displayed, and 15 medals are paid out. If the first stop operation is reel B, "NM04" (C_21 bell) is displayed and 15 medals are paid out. Furthermore, if the first stop operation is reel C, "NM09" (C_34 bells) is displayed and 15 medals are paid out.

“F_Nakadan Che 2” is configured to be determined as an internal winning combination in a non-bonus state. As shown in FIG. 44, FIG. 46, and FIG. 48, when "F_Middle Che 2" is determined as the internal winning combination, if the first stop operation is reel A or reel D, "NM16" (S_confirmed combination) ), "NM17" (S_middle tier 1), or "NM18" (S_middle tier 2) are displayed, and 15 medals are paid out. If the first stop operation is reel B, "NM04" (C_21 bell) is displayed and 15 medals are paid out. Furthermore, if the first stop operation is reel C, "NM09" (C_34 bells) is displayed and 15 medals are paid out.

“F_Weak Che” is configured to be determined as an internal winning combination in the RB interior, the BB interior, or in the bonus state. If "F_Weak Che" is determined as the internal winning combination, "NM19" (C_Weak Che A), "NM20" (S_Weak Che B), "NM22" (S_ Strong Che 2) regardless of the stop operation mode. , "NM47" (S_batting order mistake 11), or "NM55" (S_batting order mistake 19A) is displayed. As shown in FIGS. 45 and 47, if the first stop operation is reel A, reel B, or reel C in the bonus state or inside RB, there is a probability of 19/20 that "NM20" (S_ Weak Che B), "NM22" (S_Strong Che 2), "NM47" (S_Batting Order Mistake 11), or "NM55" (S_Batting Order Mistake 19A) will be displayed and one medal will be paid out. With a probability of 1/20, "NM19" (C_Weak Che A) is displayed and two medals are paid out. If the first stop operation is reel D, the probability is 18/20 that "NM20" (S_weak Che B), "NM22" (S_ strong Che 2), "NM47" (S_ batting order mistake 11), "NM55" (S_Batting order mistake 19A) is displayed and one medal is paid out, and with a probability of 2/20, "NM19" (C_Weak Che A) is displayed and two medals are paid out. In addition, in this embodiment, the pressing order is the fourth reel D, the third reel C, the second reel B, and the first reel A, and the stop operation for the fourth reel D is a press that causes a cherry to be displayed at the bottom. If the timing is right, "NM19" (C_Weak Che A) is displayed and two medals are paid out. As shown in FIG. 49, if the BB is inside, there is a 1/2 probability that "NM20" (S_Weak CheB), "NM22" (S_Strong Che2), or "NM47" will occur regardless of the stop operation mode. Either (S_batting order mistake 11) or "NM55" (S_batting order mistake 19A) is displayed and one medal is paid out, and "NM19" (C_weak Che A) is displayed with a probability of 1/2. Two medals will be paid out.

“F_Strong Che 1” is configured to be determined as an internal winning combination in the RB interior, the BB interior, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_Strong Che 1" is determined as the internal winning combination, if the first stop operation is reel A or reel D, "NM21" (S_Strong Che 1), "NM22" (S_Strong Che 2), or "NM23" (S_Strong Che 3) is displayed, and one medal is paid out. If the first stop operation is reel B or reel C, either "NM20" (S_weak Che B), "NM30" (S_batting order mistake 01), or "NM47" (S_batting order mistake 11) is displayed, One medal is paid out.

“F_Strong Che 2” is configured to be determined as an internal winning combination in the RB interior, the BB interior, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_Strong Che 2" is determined as the internal winning combination, if the first stop operation is reel A or reel D, "NM22" (S_Strong Che 2) is displayed and one medal is paid out. If the first stop operation is reel B or reel C, either "NM20" (S_weak Che B), "NM30" (S_batting order mistake 01), or "NM47" (S_batting order mistake 11) is displayed, One medal is paid out.

“F_Weak Watermelon 1” is configured to be determined as an internal winning combination in the RB interior, the BB interior, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_Weak Watermelon 1" is determined as the internal winning combination, if the first stop operation is reel A or reel D, "NM26" (C_BL Watermelon 1) ), "NM28" (C_CL Watermelon 1) is displayed, and one medal is paid out. If the first stop operation is reel B or reel C, "NM30" (S_batting order mistake 01) is displayed and one medal is paid out.

“F_Weak Watermelon 2” is configured to be determined as an internal winning combination in the RB interior, the BB interior, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_Weak Watermelon 2" is determined as the internal winning combination, if the first stop operation is reel A or reel D, "NM24" (C_XU Watermelon 1 ), "NM28" (C_CL Watermelon 1) is displayed, and one medal is paid out. If the first stop operation is reel B or reel C, "NM30" (S_batting order mistake 01) is displayed and one medal is paid out.

“F_Strong Watermelon 1” is configured to be determined as an internal winning combination in the RB interior, the BB interior, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_strong watermelon 1" is determined as the internal winning combination, if the first stop operation is reel A or reel D, "NM26" (C_BL watermelon 1 ), "NM27" (C_BL Watermelon 2), "NM28" (C_CL Watermelon 1), or "NM29" (C_CL Watermelon 2) are displayed, and one medal is paid out. If the first stop operation is reel B or reel C, "NM30" (S_batting order mistake 01) is displayed and one medal is paid out.

“F_Strong Watermelon 2” is configured to be determined as an internal winning combination in the RB interior, the BB interior, or in the bonus state. As shown in FIGS. 45, 47, and 49, when "F_Strong Watermelon 2" is determined as the internal winning combination, if the first stop operation is reel A or reel D, "NM24" (C_XU Watermelon 1 ), "NM25" (C_XU watermelon 2), "NM28" (C_CL watermelon 1), or "NM29" (C_CL watermelon 2) are displayed, and one medal is paid out. If the first stop operation is reel B or reel C, "NM30" (S_batting order mistake 01) is displayed and one medal is paid out.

“F_RB1 piece 01” to “F_RB1 piece 12” are configured to be determined as internal winning combinations within RB or within BB. As shown in FIG. 47, when the RB is inside, "F_RB 1 piece 01" to "F_RB 1 piece 12" are 4 choices (any one of the 4 batting orders) consisting of the selection of the first stop operation. If the stop operation is performed in the corresponding correct pressing order, the following combinations will be played: "NM30" - "NM33", "NM56" - " NM61" is displayed and one medal is paid out. On the other hand, if the stop operation is not performed in the corresponding correct press order (the stop operation is performed in the incorrect press order), "RB" (C_RB) may be displayed. For example, when "F_RB1 piece 01" is determined as the internal winning combination, if the first stop operation is reel A, the correct answer press order will be "NM30" (S_batting order mistake 01), "NM56" (C_batting order mistake 19B) or "NM59" (C_batting order mistake 20B) is displayed, and one medal is paid out. On the other hand, if the first stop operation is not reel A, the pressing order will be incorrect, with a probability of 1/3 of "NM30" (S_batting order mistake 01), "NM56" (C_batting order mistake 19B), "NM59 ( C_batting order mistake 20B) is displayed, and one medal is paid out. If none of "NM30", "NM56", and "NM59" can be displayed, "RB" (C_RB) is displayed.

As shown in FIG. 49, if "F_RB1 piece 01" to "F_RB1 piece 12" are determined as internal winning combinations when the BB is inside, "NM30" to "NM33" are determined as internal winning combinations regardless of the stop operation mode. , "NM56" to "NM61" are displayed, and one medal is paid out. For example, if "F_RB1 piece 01" is determined as the internal winning combination, either "NM30" (S_batting order mistake 01), "NM56" (C_batting order mistake 19B), or "NM59" (C_batting order mistake 20B) is displayed and one medal is paid out.

“F_Exclusive 1 piece 1” is configured to be determined as an internal winning combination within the RB or within the BB. As shown in FIGS. 47 and 49, when "F_exclusive 1 piece 1" is determined as the internal winning combination, regardless of the stop operation mode, there is a 1/3 probability of "NM31" (C_batting order mistake 02A), Either "NM37" (C_batting order mistake 06A) is displayed and one medal is paid out. Furthermore, there is a probability of 2/3 that none of the display combinations will be displayed.

“F_Exclusive 1 piece 2” is configured to be determined as an internal winning combination within the RB or within the BB. As shown in FIGS. 47 and 49, when "F_exclusive 1 piece 2" is determined as the internal winning combination, regardless of the stop operation mode, there is a 1/3 probability of "NM32" (C_batting order mistake 02B), Either "NM38" (C_batting order mistake 06B) is displayed and one medal is paid out. Furthermore, there is a probability of 2/3 that none of the display combinations will be displayed.

“F_Exclusive 1 piece 3” is configured to be determined as an internal winning combination within the RB or within the BB. As shown in FIGS. 47 and 49, when "F_exclusive 1 piece 3" is determined as the internal winning combination, regardless of the stop operation mode, there is a 1/3 probability of "NM33" (C_batting order mistake 02C), Either "NM39" (C_batting order mistake 06C) is displayed and one medal is paid out. Furthermore, there is a probability of 2/3 that none of the display combinations will be displayed.

“F_Common 1 piece A” is configured so that it can be determined as an internal winning combination within RB, within BB, or in a bonus state. As shown in FIGS. 45, 47, and 49, when "F_Common 1 piece A" is determined as the internal winning combination, "NM31" (C_batting order mistake 02A), "NM32" regardless of the stop operation mode. (C_batting order mistake 02B), "NM33" (C_batting order mistake 02C), "NM37" (C_batting order mistake 06A), "NM38" (C_batting order mistake 06B), "NM39" (C_batting order mistake 06C) is displayed and one medal is paid out.

“F_Common 1 piece B” is configured so that it can be determined as an internal winning combination in RB inside, BB inside, or in a bonus state. As shown in FIGS. 45, 47, and 49, when "F_common 1 piece B" is determined as the internal winning combination, "NM34" (S_batting order mistake 03), "NM40" regardless of the stop operation mode. (C_batting order mistake 07A), "NM41" (C_batting order mistake 07B), or "NM42" (C_batting order mistake 07C) is displayed and one medal is paid out.

“F_batting order BB01” to “F_batting order BB10” are configured to be determined as an internal winning combination in RB inside, BB inside, or in a bonus state. As shown in FIGS. 45 and 47, when "F_ batting order BB01" to "F_ batting order BB10" are determined as internal winning combinations when RB is in the internal or bonus state, " Any one of "NM40", "NM41", "NM44", "NM45", "NM62" to "NM80" is displayed, and one medal is paid out. For example, if "F_batting order BB01" is determined as an internal winning combination, "NM44" (C_batting order mistake 08B), "NM45" (S_batting order mistake 09), "NM62" (C_BBFLW), "NM63" (C_BBK1A) ), "NM64" (C_BBK1B), "NM65" (C_BBK1C), and "NM76" (C_BBK common 2) are displayed, and one medal is paid out.

As shown in FIG. 49, if "F_ batting order BB01" to "F_ batting order BB09" are determined as internal winning combinations when the BB is inside, it is configured by selecting the first and second stop operations. The pressing order is BB with 12 choices (any one of the 12 batting orders is the correct pressing order). If the stop operation is performed in the corresponding correct pressing order, there is a 3/4 probability that "BB" (C_BB) will be displayed, and a 1/4 probability that "NM41", "NM44", "NM45", Either "NM63" to "NM72" or "MN75" to "MN80" is displayed. On the other hand, if the stop operation is not performed in the corresponding correct pressing order, there is a 1/4 probability of "NM41", "NM44", "NM45", "NM63" ~ "NM72", "MN75" ~ " MN80'' is displayed, and there is a probability of 3/4 that no display combination is displayed. For example, if "F_batting order BB01" is determined as the internal winning combination, if the first stop operation is reel A and the second stop operation is reel B, the correct press order will be used, and there is a probability of 3/4 that it will be "BB". (C_BB) is displayed, and one of "NM44", "NM45", "NM62" to "NM65", and "MN76" is displayed with a probability of 1/4. On the other hand, if the first stop operation is not reel A and the second stop operation is not reel B, there is a 1/4 probability that one of "NM44", "NM45", "NM62" to "NM65", or "MN76" will be selected. displayed, and there is a 3/4 probability that none of the display combinations will be displayed.

As shown in FIG. 49, if "F_batting order BB10" is determined as the internal winning combination when it is inside BB, 4 choices (out of 4 batting orders) consisting of the selection of the first stop operation are selected. Any one of the batting orders is the correct pressing order), and the pressing order is BB. If the stop operation is performed in the corresponding correct press order (the first stop operation is reel D), "BB" (C_BB) will be displayed with a probability of 9/16, and "NM40" will be displayed with a probability of 7/16. , "NM62", "NM73", or "MN74" is displayed. On the other hand, if the stop operation is performed outside the corresponding correct press order (the first stop operation is other than reel D), there is a 1/4 probability that "NM44", "NM45", "NM62" ~ "NM65" will be displayed. , "MN76" are displayed, and with a probability of 3/4, neither display combination is displayed.

"RB+F_Weak Che", "RB+F_Strong Che 1", "RB+F_Strong Che 2", "RB+F_Weak Watermelon 1", "RB+F_Weak Watermelon 2", "RB+F_Strong Watermelon 1", "RB+F_Strong Watermelon 2", "BB+F_RB1" Sheet 01” to “BB+F_RB1 sheet 12”, “RB+F_Exclusive 1 sheet 1”, “RB+F_Exclusive 1 sheet 2”, “RB+F_Exclusive 1 sheet 3”, “RB+F_Common 1 sheet A”, “BB+F_Common 1 sheet B”, “RB+F_batting order BB01” to “RB+F_batting order BB10” are configured to be determined as internal winning combinations in the RT0 state or RT1 state. That is, in the case of the normal state (RT0 state, RT1 state), "RB" is "F_Weak Che", "F_Strong Che 1", "F_Strong Che 2", "F_Weak Watermelon 1", "F_ "Weak watermelon 2", "F_strong watermelon 1", "F_strong watermelon 2", "F_exclusive 1 piece 1", "F_exclusive 1 piece 2", "F_exclusive 1 piece 3", "F_common 1 piece A" , "F_batting order BB01" to "F_batting order BB10" will be won in duplicate.

As shown in FIG. 45, "RB+F_Weak Che", "RB+F_Strong Che 1", "RB+F_Strong Che 2", "RB+F_Weak Watermelon 1", "RB+F_Weak Watermelon 2", "RB+F_Strong Watermelon 1", "RB+F_ Suspension of "Strong Watermelon 2", "RB+F_exclusive 1 piece 1", "RB+F_exclusive 1 piece 2", "RB+F_exclusive 1 piece 3", "RB+F_common 1 piece A", "RB+F_batting order BB01" to "RB+F_batting order BB10" The correspondence between the operation modes and the display combinations is shown in FIG. "F_Strong Watermelon 1", "F_Strong Watermelon 2", "F_Exclusive 1 piece 1", "F_Exclusive 1 piece 2", "F_Exclusive 1 piece 3", "F_Common 1 piece A", "F_ Batting order BB01" This is the same as the correspondence between the stop operation mode and the display combination for "F_batting order BB10". That is, in the general state (RT0 state, RT1 state), "RB" is "F_Weak Che", "F_Strong Che 1", "F_Strong Che 2", "F_Weak Watermelon 1", "F_Weak Watermelon 2". ”, “F_strong watermelon 1”, “F_strong watermelon 2”, “F_exclusive 1 piece 1”, “F_exclusive 1 piece 2”, “F_exclusive 1 piece 3”, “F_common 1 piece A”, “F_ In a game in which a winning is made in duplicate with any one of "batting order BB01" to "F_batting order BB10", the combination of symbols related to "RB" is not displayed regardless of the stop operation mode (see FIG. 45).

On the other hand, in a game in which any one of "F_RB 1 piece 01" to "F_RB 1 piece 12" is won while inside RB (state between RB flags), a combination of symbols related to "RB" may be displayed (Fig. 47). In other words, in a game where any one of "F_RB 1 piece 01" to "F_RB 1 piece 12" is won while inside RB (state between RB flags), if the stop operation is performed in the correct order, the symbols related to "RB" The combinations are not displayed, but the combinations of symbols for which one medal is paid out are displayed. Then, if the stop operation is not performed in the correct pressing order, a symbol combination related to "RB" is displayed when a symbol combination for which one medal is paid out is not displayed.

Further, in the case of the general state (RT0 state, RT1 state), "BB" is won in duplicate with any of "F_RB1 piece 01" to "F_RB1 piece 12" and "F_Common 1 piece B". As shown in FIG. 45, the correspondence relationship between the stop operation modes of "BB+F_RB1 piece 01" to "BB+F_RB1 piece 12" and "BB+F_Common 1 piece B" and the display combinations is as shown in FIG. 47, "F_RB1 piece 01" to " This is the same as the correspondence between the stop operation mode and the display combination for "F_RB 1 piece 12" and "F_Common 1 piece B". In other words, in the general state (RT0 state, RT1 state), in a game where "BB" is won in duplicate with any of "F_RB 1 piece 01" to "F_RB 1 piece 12" or "F_common 1 piece B", the stop operation is performed. Regardless of the mode, the combination of symbols related to "BB" is not displayed (see FIG. 45).

On the other hand, in a game where any of "F_batting order BB01" to "F_batting order BB10" is won while inside the BB (state between BB flags), a combination of symbols related to "BB" may be displayed (Fig. 49). That is, in a game in which any one of "F_ batting order BB01" to "F_ batting order BB10" is won within the BB, if the stop operation is performed in the correct pressing order, the combination of symbols that will pay out one medal will be If not displayed, a combination of symbols related to "BB" is displayed. If the stop operation is not performed in the correct pressing order, the combination of symbols related to "BB" may not be displayed, but the combination of symbols that pays out one medal may be displayed.

[Game performance of second gaming machine]
Next, with reference to FIG. 50, the flow of the game in the second gaming machine will be explained. FIG. 50 is a diagram showing an example of the transition flow of gaming states in the non-advantageous section and the advantageous section in the second gaming machine.

[Transition of gaming state]
As shown in FIG. 50, in the second gaming machine, the state in which the player plays the game is roughly divided into a non-advantageous section and an advantageous section, and the advantageous section further includes a normal section, a pseudo-bonus section, and a continuous chance section. Zone sections are provided. The non-advantageous section is a gaming state (non-AT state) in which information on a stop operation that is advantageous to the player is not reported, and is a gaming state that is disadvantageous to the player. The non-advantageous section is the initial state that is controlled when the game in the advantageous section ends, when a setting change operation is performed, when other initialization conditions are met, or at the time of factory shipment. state.

The normal section is a gaming state (non-AT state) in which information on stop operations that are advantageous to the player is not reported, and is similar to the non-advantageous section in that it is a gaming state that is disadvantageous to the player. , differs from the non-advantageous section in that the map type is determined. The normal section is a control state as a normal state in which the player plays a normal game, in which the degree of expectation for transition (granting) to the pseudo-bonus section can be varied depending on the map type and the like. The pseudo bonus period is a gaming state (AT state) in which information on a stop operation that is advantageous to the player is notified, and is a gaming state that is advantageous to the player. That is, the pseudo-bonus period is a control state as an advantageous state in which the player can increase the number of medals.

In addition, the continuous zone zone is a gaming state (non-AT state) in which information on stop operations that are advantageous to the player is not reported, and is a gaming state that is disadvantageous to the player, similar to the non-advantageous section. As will be described later, this differs from the non-advantageous section in that map migration is performed. The continuous winning zone section is a control state in which the degree of expectation of transition to the pseudo bonus section (granting) can be varied depending on the map type, etc., and is a normal state in which the player plays a normal game. Furthermore, in the continuous zone zone, it is possible to determine a map type different from that in the normal zone, and there is a higher degree of expectation for transition (granting) to the pseudo bonus zone than in the normal zone.

In the non-advantageous section, it is determined for each game whether the conditions for shifting to the advantageous section are satisfied. When the advantageous section transition conditions are met, the non-advantageous section is transferred to the advantageous section. In the second gaming machine, the advantageous section transition condition is that a predetermined internal winning combination is determined. The predetermined internal winning combinations are ones other than "Unfair (only in RB/BB)", "F_Normal Rip 2", "F_Normal Rip 3", "1 in F_RB", and "Bell in F_RB". He is playing a role. Note that the transition from the non-advantageous section to the advantageous section is also possible in the RB inter-flag state, the BB flag inter-state, the RB operating state, and the BB operating state.

Furthermore, in the non-advantageous section, when a predetermined internal winning combination is determined, whether the pseudo bonus is won or not is determined. The types of pseudo bonuses that can be determined in this case are "REG bonus," "BIG bonus," and "super BIG bonus." Further, if a predetermined internal winning combination is determined in the non-advantageous section and a "REG bonus" is determined, the type of pseudo bonus is changed to a "BIG bonus". Note that if a predetermined internal winning combination is determined in the non-advantageous section and a "BIG bonus" or "super BIG bonus" is determined, the type of pseudo bonus is not changed. However, when a predetermined internal winning combination is determined in a non-advantageous section and a "BIG bonus" is determined, the type of pseudo bonus may be changed to a "super big bonus" or other benefits may be granted. Good too.

For the game following the game that has transitioned to the advantageous section (hereinafter referred to as the "next game after the transition to the advantageous section"), a table type lottery, which will be described later, is carried out, and the table type is determined according to the RT status at that time. Ru. The determined table type is basically not changed until the pseudo bonus is determined. In addition, in the normal section and consecutive winning zone section of the advantageous section, the map type is determined according to the table type, and whether the pseudo bonus is won or not is determined according to the determined map type. When it is determined that the pseudo bonus has been won, it is determined to move to the pseudo bonus section.

When the RT state in the 1st G of the advantageous section is the RT0 state, it is easier to determine a table type that is advantageous to the player than when the RT state is in the RT1 to RT3 states. The table type that is advantageous for the player is likely to be the map type that is advantageous for winning the pseudo bonus. Therefore, when the RT state in the 1st G of the advantageous section is the RT0 state, the probability of winning the pseudo bonus is higher than when it is the RT1 or RT2 state.

(Normal section)
Unless the non-advantageous section is directly transferred to the pseudo-bonus section, the transition to the advantageous section basically starts from the normal section. The normal section includes a high probability zone and a BIG certainty zone. In the normal section, the map type is determined every predetermined period (approximately 200G). In addition, in the normal section, winning or non-winning of the pseudo bonus is determined depending on the map type. The high probability zone is set from 1 to 200G in the normal section. The types of pseudo bonuses that can be determined in the high probability zone are "REG bonus", "BIG bonus", and "super BIG bonus". The high probability zone has a higher degree of expectation that a pseudo bonus will be determined than the BIG certainty zone. In the high probability zone, when a pseudo bonus is determined, the probability that a "REG bonus" is determined and the probability that a "BIG bonus" is determined are set to be approximately the same. Note that, in the gaming machine according to the present invention, the probability that a "REG bonus" is determined and the probability that a "BIG bonus" is determined when winning a pseudo bonus may be made different. For example, if pseudo bonuses are determined a certain number of times in a row in a high probability zone, and the type of pseudo bonuses are all "REG bonuses", the probability of "REG bonus" being determined is higher than the "BIG bonus". ” may be determined with a higher probability.

When the type of pseudo bonus is determined in the high probability zone, the number of precursor Gs (games) is determined, and in the final game of the number of precursor Gs, the determined (granted) type of pseudo bonus is notified. Hereinafter, the number of precursor Gs determined when the pseudo bonus is determined will be referred to as the actual precursor G number, and the game until the actual precursor G number is reached will be referred to as the actual precursor G number. If the "REG bonus" is determined during the high probability zone and the zone shifts to the BIG certainty zone during the main sign, the determined "REG bonus" is changed to the "BIG bonus". On the other hand, if a "BIG bonus" or "super BIG bonus" is determined in the high probability zone and the game is transferred to the BIG certain zone while playing the game of the actual precursor G number, the type of the determined pseudo bonus is not changed.

The BIG sure zone is set from 201G in the normal section to the ceiling. The ceiling of the BIG certain zone is 951G + the number of precursor Gs. That is, the "BIG bonus" or "super big bonus" is determined in 951G of the advantageous section, and the determination (granting) of the pseudo bonus and the type of the pseudo bonus are announced in the final game of the number of portent Gs determined at that time. Ru. The types of pseudo bonuses that can be determined in the BIG certain zone are "BIG bonus" and "super BIG bonus". That is, if a pseudo bonus is not won by 200G in an advantageous section, the pseudo bonus won after that will always be a "BIG bonus" or a "super BIG bonus."

In the normal section, it is possible to determine a fake precursor. When a fake omen is determined, the number of fake omen G is determined, and it is notified that a pseudo bonus will not be determined (granted) in the final game of that number of fake omen G. Hereinafter, the game until the number of fake precursor G is reached will be referred to as during fake precursor. In the normal section, a pseudo bonus can be determined during a fake sign. When a pseudo bonus is determined (granted) during a fake omen, if the remaining fake omen G number is equal to or greater than a predetermined number, the fake omen is rewritten to a real omen without changing the omen G number. In this case, the type of pseudo bonus determined (granted) in the final game of the determined number of portent Gs is notified. Furthermore, when a pseudo bonus is determined (granted) during a fake omen, if the remaining fake omen G number is less than a predetermined number, the omen G number is extended and the fake omen is rewritten into a real omen. In this case, the type of pseudo bonus determined (granted) in the final game of the extended number of portent Gs is notified.

(pseudo bonus section)
The pseudo-bonus section includes a "REG bonus," a "BIG bonus," and a "super BIG bonus." The "REG bonus" starts from the next game in which the determined (granted) type of pseudo bonus is announced. The termination condition for the "REG bonus" is that the number of press order navigations when winning a press order small winning combination reaches the first specified number. With the "REG bonus" according to this embodiment, approximately 75 medals can be acquired. When the "REG bonus" ends, the pseudo-bonus section and the advantageous section end, and the period shifts to the non-advantageous section.

The "BIG bonus" starts from the next game in which the determined (granted) type of pseudo bonus is announced. The condition for ending the "BIG bonus" is that the push order navigation when winning the push order small winning combination reaches the second specified number. With the "BIG bonus" according to this embodiment, approximately 500 medals can be acquired. When the "BIG bonus" ends, the continuous zone section starts. Also, during the "BIG bonus", a "1G consecutive" lottery will be held. If you win the "1G consecutive" lottery, "BIG bonus" will be stocked. When the "BIG bonus" is stocked, the main display device 210 or the like will notify that the "BIG bonus" has been won (granted) in the 1st G of the continuous winning zone section. Then, the "BIG bonus" starts from the next game. “1G consecutive” lottery is held when “Strong Che” (“F_Strong Che 1”, “F_Strong Che 2”) is won, and if it is not won, the combination of symbols related to “batting order mistake” will be displayed. The pressing order (batting order navigation) is displayed to prevent the player from knowing that he or she has won the "strong game". On the other hand, when the "1G consecutive" lottery at the time of winning "Strong Che" is a win, the pressing order (batting order navigation) is not displayed. In other words, if you win the "1G consecutive" lottery at the time of winning "Strong Che", if the first stop operation is reel A or reel D, the combination of symbols (NM21 to NM23) related to "Strong Che" will be displayed. be done. Thereby, it is possible to suggest to the player that he has won the "1G consecutive" lottery. In addition, the "1G consecutive" lottery is held when "1 RB" ("F_RB 1 piece 01" to "F_RB 1 piece 12") is won, and in this case, the correct answer press order (batting order navigation) regardless of winning or non-winning. Display. Note that if the "1G consecutive" lottery has already been won and the "BIG bonus" is stocked, the "1G consecutive" lottery will not be performed even if the "strong Che" or "1 RB" lottery is won.

The "Super BIG Bonus" starts from the next game in which the determination (granting) of the pseudo bonus and the type of the pseudo bonus have been announced. The "super big bonus" is the winning of the "BIG bonus" and the determination of the "BIG bonus" stock. That is, when the determination (award) of the "Super BIG Bonus" is notified by the main display device 210 etc., the "BIG Bonus" will start from the next game, and when the "BIG Bonus" ends, the "BIG Bonus" will be played in the continuous chance zone section. Transition. Then, in the 1st G of the consecutive winning zone section, the determination (granting) of the "BIG bonus" is announced by the main display device 210 or the like, and the "BIG bonus" starts from the next game. Therefore, with the "Super BIG Bonus" according to this embodiment, it is possible to obtain approximately 1000 medals.

If "RB" and "BB" become activated during a pseudo bonus (AT), the pseudo bonus is temporarily interrupted and a special state is started. In the special state, the number of medals reduced during the operation of "RB" and "BB" is counted. Then, after the operation of "RB" and "BB" is completed, the reduced amount of medals is returned by performing navigation (that is, informing the player of information on the stop operation that is advantageous to the player regarding the combination related to the payout of medals). do. Specifically, a value obtained by dividing the number of medals that decreased during the operation of "RB" and "BB" by 12 (the remainder is rounded down) is set as the number of times of navigation. Furthermore, during the special state, the main display device 210 or the like displays "Returning to state" to inform the player that the pseudo bonus is temporarily suspended. The special state ends when the set number of navigations (returning the reduced amount of medals) is completed, and when the game stop operation is completed when the game is in RB (carryover). , to return to pseudo-bonuses.

(Renchan zone section)
The continuous zone zone is set to a maximum of 100G after the end of the "BIG bonus". In the 1G of the continuous zone section, the table type is determined, and the map type is determined according to the table type. The table type of the continuous winning zone section is determined according to the remaining period (number of games) of the advantageous section or whether or not a pseudo bonus has been determined. In addition, in the continuous winning zone section, winning or non-winning of the pseudo bonus is determined according to the map type.

The types of pseudo bonuses that can be determined in the continuous winning zone section are "BIG bonus" and "super big bonus". That is, when a pseudo bonus is determined in the consecutive winning zone, it is determined that the transition to the consecutive winning zone section occurs after the pseudo bonus section ends. The continuous chance zone section has a higher degree of expectation that a pseudo bonus will be determined than the high probability zone and the BIG certain zone. Note that if the winning of the pseudo bonus is determined before moving to the continuous winning zone section, the winning of the pseudo bonus will not be determined in the continuous winning zone section.

In the continuous zone section, it is possible to determine a fake sign. When a fake omen is determined, the number of fake omen G is determined, and a fake omen performance is performed over the number of fake omen G. In the fake omen performance, it is announced that a pseudo bonus will not be determined (granted) in the final game. When the fake omen ends, the consecutive chance zone section ends, and the advantageous section ends. As a result, the advantageous section shifts to the non-advantageous section. Moreover, as a consecutive chance zone section, there is one in which a fake omen effect starts at the same time as the start (immediate omen). In this case, even if the fake omen performance ends, the consecutive winning zone section does not end, and the advantageous section does not end either. In the present embodiment, the end condition of the continuous chance zone section is the end of the fake sign, but the end condition of the continuous chance zone section according to the present invention can be set as appropriate. For example, the number of games in the consecutive zone zone may be determined when the game shifts to the consecutive zone zone. Further, the number of games in the continuous zone section may be set to a predetermined fixed value.

(Advantageous section upper limit processing)
The second gaming machine executes limit processing in the same way as the first gaming machine described above (see FIG. 1). As the limit processing, the above-mentioned game number limiter (1500 games) and payout number limiter (2400 coins) are employed. In the second gaming machine, in the normal section, when the number of medals paid out during the advantageous section exceeds a first specific number (for example, "1400"), or when the value of the advantageous section game number counter reaches the first specific value. (For example, "1350") or more, the "super big bonus" and "1G consecutive" lottery will not be performed. In other words, if there is a possibility that limit processing will be carried out that would prevent the player from fully enjoying the benefits of the "Super BIG Bonus" or "1G Consecutive", the winning of the "Super BIG Bonus" or "1G Consecutive" You can choose not to decide. Thereby, it is possible to prevent the player from feeling uncomfortable. In addition, in the normal section, the value of the advantageous section game counter is equal to or less than the second specific value (for example, "1479"), and the number of medals paid out during the advantageous section is equal to or greater than the second specific number (for example, "2200"). or when the value of the advantageous section game number counter reaches the second specific value, the "BIG bonus" is determined (granted), and the "BIG bonus" is determined (granted) by the main display device 210 or the like. inform.

In the pseudo-bonus section, if the number of medals paid out during the advantageous section exceeds the payout limiter (2400 pieces), or if the value of the advantageous section game number counter reaches the number of games limiter (1500 games), the pseudo-bonus will be issued. (advantageous section) is completed, and the end of the pseudo bonus (advantageous section) is notified by the main display device 210 or the like. Additionally, in the pseudo-bonus period, the value of the advantageous period game counter is less than or equal to the second specific value (e.g., "1479"), and the number of medals paid out during the advantageous period is greater than or equal to the second specific number (e.g., "2200"). When this happens, or when the value of the advantageous section game counter reaches the second specific value, the main display device 210 or the like executes an ending effect that announces the ending. When the pseudo-bonus with the ending effect ends, the advantageous section ends without moving to the continuous zone zone. Furthermore, during the pseudo-bonus with the ending effect, if the number of medals paid out during the advantageous section exceeds the payout limiter (2400 pieces), or the value of the advantageous section game number counter is the number of games limiter (1500 games). In this case, even if the pseudo bonus is in the middle, the pseudo bonus ends and the advantageous section ends. In addition, if the upper limit of the advantageous period is reached while pseudo bonus (AT) and "RB" and "BB" are activated, the end of the advantageous period will be displayed on the main screen when the next game start operation is performed. Notification is made by the device 210 or the like.

Note that the second gaming machine may execute limit processing for advantageous sections using only the number of games limiter, may execute limit processing for advantageous sections using only the number of payouts limiter, and may perform limit processing for advantageous sections using only the number of payout limiters. The advantageous section limit processing may be executed using both a limiter and a payout number limiter. Note that when using both limiters, it is desirable to end the advantageous section when the operating condition for either limiter is satisfied after the start of the advantageous section.

Further, the type of limiter is not limited to the above-mentioned game number limiter and payout number limiter. For example, the number of navigation times for the small winning combination in the push order during the AT state (that is, the number of times information on a stop operation advantageous to the player was notified regarding the winning combination related to the payout of medals) is a predetermined number of times (for example, "400" times). A navigation number limiter may be provided that executes the limit process when the number of times the navigation is reached. That is, as long as the gambling nature can be appropriately suppressed, it is possible to execute the limit process using various conditions related to the game.

[High probability zone/BIG certainty zone table]
Next, the high probability zone and BIG probability zone tables will be described with reference to FIGS. 51 and 52. FIG. 51 is a table list of high probability zones and BIG probability zones related to the second gaming machine. FIG. 52 is a table of high probability zones and BIG probability zones and a correspondence table of zones related to the second gaming machine.

As shown in FIG. 51, the table types for the high probability zone and the BIG certainty zone are tables A to E. As described above, the table types for the high probability zone and the BIG certain zone are determined by the table type lottery held in the next game after the transition to the advantageous section. Once the table type is determined, it basically remains unchanged until a pseudo bonus (REG bonus, BIG bonus, super BIG bonus) is won. Then, the MAP type is determined according to the table type. The MAP type influences the degree of expectation of winning a pseudo bonus.

As shown in FIG. 51, table A is a basic table and is a table type that is easier to determine than tables B to E. When table A is determined, the number of games (ceiling) until the pseudo bonus is definitely determined is the largest. As shown in FIG. 52, when table A is determined, the expectation level at which a pseudo bonus is determined (hereinafter referred to as "AT winning expectation level") is "low" in the advantageous section 51 to 100G. Become. The AT winning expectation level is "blank", "low", "medium", "high", and "confirmed", and the AT winning expectation level "blank" has the lowest expectation, "blank", "low", Expectations increase in the order of "medium," "high," and "determined." It should be noted that during the period (zone) where the AT winning expectation level is "confirmed", a pseudo bonus is always determined. When table A is determined, the AT winning expectation becomes "confirmed" in the advantageous section from 951 to 1000G, and a pseudo bonus is definitely determined. In addition, when table A is determined, the AT winning expectation level is "high" in the advantageous section 151 to 200G, and the probability of a pseudo bonus being determined is higher than in other periods except for the advantageous section 951 to 1000G. It gets expensive.

As shown in FIG. 51, table B is a chance table A with a higher degree of expectation than table A in which a pseudo bonus is determined. When table B is determined, the number of games (ceiling) until a pseudo bonus is definitely determined is smaller than when table A is determined. As shown in FIG. 52, when table B is determined, the AT winning expectation becomes "confirmed" in the advantageous section 751 to 800G, and the pseudo bonus is definitely determined. In addition, when Table B is determined, the AT winning expectation level is "high" in the advantageous section 151 to 200G, and the probability of a pseudo bonus being determined is higher than in other periods except for the advantageous section 751 to 800G. It gets expensive.

As shown in FIG. 51, table C is a chance table B with a higher degree of expectation than table A in which a pseudo bonus is determined. When table C is determined, the number of games (ceiling) until a pseudo bonus is definitely determined is smaller than when table B is determined. As shown in FIG. 52, when table C is determined, the AT winning expectation level becomes "confirmed" in the advantageous section 551 to 600G, and the pseudo bonus is definitely determined. In addition, when table C is determined, the AT winning expectation level is "high" in the advantageous section 151 to 200G, and the probability of a pseudo bonus being determined is higher than in other periods except for the advantageous section 551 to 600G. It gets expensive.

As shown in FIG. 51, table D is a chance table C with a higher degree of expectation than table A in which a pseudo bonus is determined. When table D is determined, the number of games (ceiling) until a pseudo bonus is definitely determined is smaller than when table C is determined. As shown in FIG. 52, when table D is determined, in the advantageous section 351 to 400G, the AT winning expectation becomes "confirmed" and a pseudo bonus is definitely determined. In addition, when table D is determined, the AT winning expectation level is "high" in the advantageous section 151-200G, and the probability of a pseudo bonus being determined is higher than in other periods except for the advantageous section 351-400G. It gets expensive.

As shown in FIG. 51, table E is a table in which a pseudo bonus is determined within 200 games. As shown in FIG. 52, when table E is determined, in the advantageous section 151 to 200G, the AT winning expectation becomes "confirmed" and a pseudo bonus is definitely determined. In addition, when Table E is determined, the AT winning expectation level will be "low" in the advantageous section 51 to 100G, and the probability that a pseudo bonus will be determined is higher than in other periods except for the advantageous section 151 to 200G. It gets expensive.

In the next game after transition to the advantageous section, if the RT state is the RT0 state, table A is not determined, but tables B to E are determined. Note that the table to be determined may be table D or table E, or only table E may be determined. On the other hand, if the RT state is RT1 or RT2, table A is likely to be determined. Therefore, when the RT state is the RT0 state, the degree of expectation for determining a pseudo bonus is higher than when the RT state is the RT1 or RT2 state.

For example, if you win "RB" in the non-advantageous section after initialization by setting change operation, and the symbol combination related to "RB" is not displayed in the game, the RB internal (RB In order to shift to the inter-flag state), the RT state shifts from the RT0 state to the RT2 state, and also shifts to an advantageous section in the game. Therefore, in the next game after transition to the advantageous section, the RT state becomes the RT2 state, and therefore table type lottery according to the RT0 state is not performed.

On the other hand, in the non-advantageous section after initialization by setting change operation, if you win an internal winning combination that does not overlap with "RB" or "BB" and can move to the advantageous section, the RT state does not change from the RT0 state, and moves to an advantageous section in the game. After that, if you win "RB" or "BB" in the next game after moving to the advantageous section, the RT state will shift from RT0 state to RT2 state, so normally the table type lottery according to the RT2 state would be performed. However, in this embodiment, taking into account that the RT state in the game that has shifted to the advantageous section was the RT0 state, the table type lottery is performed according to the RT0 state.

In addition, if you win "BB" in the non-advantageous section after initialization by setting change operation, and the symbol combination related to "BB" is not displayed in the game, the BB inside (BB (inter-flag state), and also to an advantageous section in the game. As described above, in the BB flag state, a lottery related to the balls to be paid (for example, an AT lottery (pseudo bonus lottery)) is not performed. Therefore, even though the player does not make any mistakes, the player is in a disadvantageous situation. Furthermore, since it is in the BB flag state (RT2 state), it would normally not be able to receive the table type lottery according to the RT0 state. Therefore, in this embodiment, the table type lottery is not performed in the BB inter-flag state, but after the transition to the BB operating state, the table type lottery according to the BB operation is performed. In the table type lottery during BB operation, tables B to E are determined in the same way as the table type lottery in response to the RT0 state.

[Renchan zone table]
Next, with reference to FIG. 53, a table of consecutive zones will be explained. FIG. 53 is a list of tables of continuous winning zones related to the second gaming machine.

As shown in FIG. 53, the table types of the continuous zone are table F to table I. The table type of the continuous chance zone will be changed depending on the type of pseudo bonus and the remaining period (number of games) of the advantageous section when "BIG bonus", "super big bonus", or "freeze" (described later) is determined. It is determined. Table F is determined when the type of pseudo bonus is "BIG bonus" and the remaining period (number of games) of the advantageous section is longer than a predetermined period (for example, 500G). Table G is determined when the type of pseudo bonus is "BIG bonus" and the remaining period (number of games) of the advantageous section is less than a predetermined period. When table G is determined, the map type in which the maximum number of games until the "BIG bonus" is determined is 100 G is not determined in the continuous zone section. On the other hand, when table F is determined, a map type is determined in which the number of games played until the "BIG bonus" is determined is a maximum of 100 G in the continuous zone section. Therefore, when table G is determined, the number of games until the "BIG bonus" is determined is smaller in the continuous zone section than when table F is determined (the period in which medals decrease is shorter). Become).

Table H is determined when the type of pseudo bonus is "freeze". "Freeze" is a pseudo-bonus that determines the "super big bonus" and increases the probability of winning the 1G series. "Freeze" is determined when the confirmed winning combination "Cherry" (F_chudan Che 1, F_chudan Che 2) is won, or when "Freeze" is won in the AT type lottery described later. When "Freeze" is determined, a lock effect is performed in the next game, and it is announced that the "Super BIG Bonus" has been determined (granted). Table I is determined when the mode is a special mode, which will be described later.

[Table type lottery table]
Next, the table type lottery table will be explained with reference to FIGS. 54 to 59. The table type lottery table is referred to for the table type lottery to be performed in the next game after transition to the advantageous section, and defines lottery value information regarding the lottery result of the table type for each setting value. Note that the probability denominator of the lottery values shown in FIGS. 54 to 59 is "256".

FIG. 54 is a table type lottery table that is referred to when the RT state is the RT0 state in the next game after transition to the advantageous section. As shown in FIG. 54, when the RT state is the RT0 state, table A is not likely to be won, and table B is likely to be won. That is, when the RT state is RT0 state in the next game after transition to the advantageous section, it is easy to win at least on the table where the pseudo bonus (AT) is determined in the advantageous section of 751 to 800G. Note that table E may be determined when the RT state is RT0 in the next game after transition to the advantageous section. In this case, since the pseudo bonus is determined in the advantageous section of 151 to 200G, the state after the setting change becomes more advantageous for the player.

FIG. 55 is a table type lottery table that is referred to when the RT state is other than the RT0 state in the next game after transition to the advantageous section. In this embodiment, a table type lottery table is provided that is referred to by the RB operating state (RT3 state) and the BB operating state (RT3 state). Therefore, the case where the RT state is other than the RT0 state substantially refers to the RT1 state and the RT2 state. As shown in FIG. 55, when the RT state is other than the RT0 state, table A is easy to win, and tables B to E are relatively hard to win. That is, if the RT state is other than the RT0 state in the next game after transition to the advantageous section, it is easy to win at least on a table where the pseudo bonus (AT) is determined at 951 to 1000G in the advantageous section.

FIG. 56 is a table type lottery table that is referred to when the RB operation state (RT3 state) is in the next game after transition to the advantageous section. When the RB is in the operating state (RT3 state), the higher the set value is, the easier it is to win on table C. In other words, in the case of the RB operating state (RT3 state) in the next game after transition to the advantageous section, the higher the setting value, the more likely it is to win a table where the pseudo bonus (AT) is determined at least in the advantageous section of 551 to 600G. Become.

FIG. 57 is a table type lottery table that is referred to when the game is in the BB operating state (RT3 state) in the next game after transition to the advantageous section. When the BB is in the operating state (RT3 state), table A cannot be won, and table B is relatively likely to be won. Also, as the set value becomes higher, it becomes easier to win on table C. In other words, if the RB is in the RB operating state (RT3 state) in the next game after transitioning to the advantageous section, it is relatively easy to win on a table where the pseudo bonus (AT) is determined at least in the advantageous section of 751 to 800G, and the set value is high. As the game progresses, it becomes easier to win on a table where the pseudo bonus (AT) is determined at least in the advantageous range of 551 to 600G.

[Each zone and MAP type]
Next, with reference to FIGS. 58 and 59, the MAP types of the high probability zone, BIG probability zone, and consecutive chance zone section will be described. FIG. 58 is a correspondence table between zones and MAP levels regarding the second gaming machine. FIG. 59 is a correspondence table between the MAP level and the pseudo bonus winning rate regarding the second gaming machine.

As shown in FIG. 58, the map types of the high probability zones are high certainty_normal A, high certainty_normal B, high certainty_normal C, and high certainty_heaven. The map type of the high probability zone is determined by a normal map lottery held in the next game after transition to the advantageous zone. Furthermore, the high probability zone is the advantageous section from 1 to 200G, and is divided into four blocks. The first block of the high probability zone is 1-50G, the second block is 51-100G, the third block is 101-150G, and the fourth block is 151G-200G. Each map type of the high probability zone defines a MAP level for each block. For example, if High Probability_Normal A is determined as the map type of the high probability zone, the first block is at MAP level 0, the second block is at MAP level 1, the third block is at MAP level 0, and the fourth block is at MAP level 0. MAP level 2.

The map types of the BIG certain zone are BIG_Normal A, BIG_Normal B, BIG_Normal C, and BIG_Heaven. The map type of the BIG certain zone is determined by a normal map lottery conducted every 200G in the BIG certain zone. The BIG certain zone is the advantageous section from 201 to 1000G, and is divided into four blocks of 200G. For example, the first block of the BIG certain zone is 201-250G, 401-450G, 601-650G, and 801-850G. The map type of the BIG certain zone is determined by a normal map lottery performed in the 1G of the first block (4 blocks). Each map type of the BIG certain zone defines a MAP level for each block. For example, if BIG_Normal A is determined as the map type of the BIG certain zone, the first block is MAP level 0, the second block is MAP level 0, the third block is MAP level 0, and the fourth block is MAP level It becomes 1.

The map types for the continuous zone zone are: continuous normal A, continuous normal B, continuous normal C, continuous normal D, continuous normal E, continuous normal F, continuous weak precursor A, continuous weak immediately. These are omen B, continuous weak omen C, continuous strong omen A, continuous strong omen B, continuous strong omen C, and continuous special omen. The continuous zone zone has a maximum of 100G after the end of the pseudo bonus, and is divided into two blocks. The first block of the consecutive chance zone section is from 1 to 50G after the end of the pseudo bonus, and the second block is from 51 to 100G after the end of the pseudo bonus.

The map type of the continuous zone zone section is determined by the continuous zone map lottery performed in the 1G of the first block. In addition, the table type referenced in the consecutive winning zone map lottery will be determined when the "BIG bonus", "super big bonus", or "freeze" that was held before the transition to the consecutive winning zone zone is determined. has been done. Each map type in the continuous zone section defines a MAP level for each block. For example, when the map type of the continuous zone section is determined as continuous_normal A, the first block becomes MAP level 0, and the second block becomes MAP level 1. Note that "Run_Special" is a map type that can be determined when the mode is a special mode, which will be described later.

As shown in FIG. 59, MAP levels 0 to 6 are provided as MAP levels related to the second game. A block with MAP level 0 has a pseudo bonus winning rate of "low". When the pseudo bonus winning rate is "low", the expected value for determining the pseudo bonus is the lowest. In the block of MAP level 0, it is determined by lottery whether or not to perform a sign (the sign includes a real sign and a fake sign). In addition, in the block of MAP level 0, it is determined by lottery whether or not to perform a forced precursor G number lottery. When the forced portent G number lottery is performed, the forced portent G number is determined, and when the game of the determined forced portent G number is played, an AT lottery according to the MAP level is performed.

A block of MAP level 1 has a pseudo bonus winning rate of "normal". The pseudo bonus winning rate "normal" has a higher expected value for determining the pseudo bonus than the pseudo bonus winning rate "low". In the block of MAP level 1, a forced precursor G number lottery is performed, so a precursor is always performed. For example, when the map type is BIG_Normal A, the first to third blocks are at MAP level 0, and the fourth block is at MAP level 1. Therefore, when the map type is BIG_Normal A, a precursor is always performed in the fourth block.

A block of MAP level 2 has a pseudo bonus winning rate of "high". When the pseudo bonus winning rate is "high", the expected value for determining the pseudo bonus is higher than when the pseudo bonus winning rate is "normal". In the block of MAP level 2, a forced precursor G number lottery is performed, so a precursor is always performed. For example, when the map type is high accuracy_normal A, high accuracy_normal B, and high accuracy_normal C, the fourth block is MAP level 2. Therefore, when the map type is Highly Certain_Normal A, Highly certain_Normal B, or Highly certain_Normal C, the expected value for determining the pseudo bonus becomes high in the fourth block.

For blocks of MAP level 3, the pseudo bonus winning rate is "certain". When the pseudo bonus winning rate is "confirmed", the pseudo bonus winning rate is confirmed. In the block of MAP level 3, a forced precursor G number lottery is performed, so a precursor is always performed. For example, if the map type is High Accuracy_Heaven, BIG_Heaven A, or BIG_Heaven B, the fourth block is MAP level 3. Therefore, if the map type is High Accuracy_Heaven, BIG_Heaven A, or BIG_Heaven B, winning of the pseudo bonus is confirmed in the fourth block.

A block of MAP level 4 has a pseudo bonus winning rate of "high". For MAP level 4 blocks, a precursor is started at the beginning. Further, in the block of MAP level 4, the forced precursor G number lottery is not performed. For example, when the map types are consecutive_quickly weak precursor A, consecutive_quickly weak precursor B, and consecutive_quickly strong precursor A consecutive_quickly strong precursor B, the first block is at MAP level 4. Therefore, if the map type is consecutive_quickly weak precursor A, consecutive_quickly weak precursor B, consecutive_quickly strong precursor A consecutive_quickly strong precursor B, at the start of the first block (after "BIG bonus" ends) The signs start to appear, and the expected value for determining the pseudo bonus increases.

For blocks of MAP level 5, the pseudo bonus winning rate is "certain". In a block of MAP level 5, a pseudo bonus is won at the start, and the real omen begins. Further, in the block of MAP level 5, a forced precursor G number lottery is performed. For example, when the map type is ``Run_Immediately weak precursor C'' or ``Run_Immediate strong precursor C'', the first block is MAP level 5. Therefore, if the map type is continuous_immediately weak precursor C or continuous_immediately strong precursor C, this precursor starts at the start of the first block (after the "BIG bonus" ends).

Blocks with MAP level 6 have a pseudo bonus winning rate of "extremely low." When the pseudo bonus winning rate is "very low", the expected value for determining the pseudo bonus is lower than when the pseudo bonus winning rate is "low". In the block of MAP level 6, a forced precursor G number lottery is performed, so a precursor is always performed. MAP level 6 is defined only for the second block when the map type is ren_special.

[Normal map lottery table]
Next, the normal map lottery table will be explained with reference to FIGS. 60 to 84. In this embodiment, the advantageous section 1 to 200G is referred to as zone 0, and the advantageous section 201 to 400G is referred to as zone 1. Further, the advantageous section 401-600G is referred to as zone 2, 601-800G is referred to as zone 3, and 801-1000G is referred to as zone 4. The normal map lottery table is referred to for the normal map lottery that is performed in the 1st G (every 200 G) of zones 0 to 4 in the advantageous section, and specifies information on the lottery values for the lottery results of map types for each set value. do. Note that the probability denominator of the lottery values shown in FIGS. 60 to 84 is "256".

FIG. 60 is a normal map lottery table that is referred to when the table type is table A in zone 0. FIG. 61 is a normal map lottery table that is referred to when the table type is table B in zone 0. FIG. 62 is a normal map lottery table that is referred to when the table type is table C in zone 0. FIG. 63 is a normal map lottery table that is referred to when the table type is table D in zone 0. FIG. 64 is a normal map lottery table that is referred to when the table type is table E in zone 0. As shown in FIGS. 60 to 64, in Zone 0, which is the advantageous section 1 to 200G, when the table types are Table A and Table B, the map type High Accuracy_Normal A wins. Further, when the table type is table D, it is possible to win the map type High Accuracy_Normal C, and when the table type is table E, the map type High Accuracy_Heaven can be won.

FIG. 65 is a normal map lottery table that is referred to when the table type is table A in zone 1. FIG. 66 is a normal map lottery table that is referred to when the table type is table B in zone 1. FIG. 67 is a normal map lottery table that is referred to when the table type is table C in zone 1. FIG. 68 is a normal map lottery table that is referred to when the table type is table D in zone 1. FIG. 69 is a normal map lottery table that is referred to when the table type is table E in zone 1. As shown in FIGS. 65 to 69, in Zone 1, which is the advantageous section 201 to 400G, when the table types are Table A and Table E, BIG_Normal A is won as the map type. Also, in the case of Table B and Table C, it is possible to win BIG_Normal A and BIG_Normal B as the map types, and in the case of Table D, it is possible to win BIG_Heaven A and BIG_Heaven B as the map types. .

FIG. 70 is a normal map lottery table that is referred to when the table type is table A in zone 2. FIG. 71 is a normal map lottery table that is referred to when the table type is table B in zone 2. FIG. 72 is a normal map lottery table that is referred to when the table type is table C in zone 2. FIG. 73 is a normal map lottery table that is referred to when the table type is table D in zone 2. FIG. 74 is a normal map lottery table that is referred to when the table type is table E in zone 2. As shown in FIGS. 70 to 74, in Zone 2, which is the advantageous section 401 to 600G, when the table types are Table B, Table D, and Table E, BIG_Normal A is won as the map type. Further, in the case of table A, it is possible to win BIG_Normal A and BIG_Normal B as the map types, and in the case of table C, it is possible to win BIG_Heaven A and BIG_Heaven B as the map types.

FIG. 75 is a normal map lottery table that is referred to when the table type is table A in zone 3. FIG. 76 is a normal map lottery table that is referred to when the table type is table B in zone 3. FIG. 77 is a normal map lottery table that is referred to when the table type is table C in zone 3. FIG. 78 is a normal map lottery table that is referred to when the table type is table D in zone 3. FIG. 79 is a normal map lottery table that is referred to when the table type is table E in zone 3. As shown in FIGS. 75 to 79, in Zone 3, which is the advantageous section 601 to 800G, when the table types are Table A, Table C to Table E, BIG_Normal A is won as the map type. Furthermore, in the case of table B, BIG_Heaven A and BIG_Heaven B can be won as map types.

FIG. 80 is a normal map lottery table that is referred to when the table type is table A in zone 4. FIG. 81 is a normal map lottery table that is referred to when the table type is table B in zone 4. FIG. 82 is a normal map lottery table that is referred to when the table type is table C in zone 4. FIG. 83 is a normal map lottery table that is referred to when the table type is table D in zone 4. FIG. 84 is a normal map lottery table that is referred to when the table type is table E in zone 4. As shown in FIGS. 80 to 84, in zone 4, which is the advantageous section 801 to 1000G, when the table type is table A, BIG_Heaven A is won as the map type. Further, in the case of tables B to E, BIG_Normal A is selected as the map type.

[Renchan Zone Map Lottery Table]
Next, the continuous zone map lottery table will be explained with reference to FIGS. 85 to 88. The continuous zone map lottery table is referred to for the continuous zone map lottery to be held in the 1st G of the continuous zone in the advantageous section, and defines information on lottery values for lottery results of map types for each set value. Note that the probability denominator of the lottery values shown in FIGS. 85 to 88 is "256".

FIG. 85 is a consecutive winning zone map lottery table that is referred to when the table type is table F in the consecutive winning zone. FIG. 86 is a consecutive winning zone map lottery table that is referred to when the table type is table G in the consecutive winning zone. FIG. 87 is a consecutive winning zone map lottery table that is referred to when the table type is table H in the consecutive winning zone. FIG. 88 is a continuous zone map lottery table that is referred to when the table type is table I in the continuous zone.

As described above, table F is determined when the remaining period (number of games) of the advantageous section is equal to or longer than a predetermined period. As shown in FIG. 85, in the case of table F in the continuous zone, it is easy to win continuous_normal A, continuous_normal B, and continuous_normal C as map types. For consecutive normal A, continuous normal B, and continuous normal C, the expected value of winning the pseudo bonus is higher in the second block than in the first block in the continuous winning zone section (see FIG. 58). On the other hand, table G is determined when the remaining period (number of games) of the advantageous section is less than a predetermined period. As shown in FIG. 86, in the case of table G in the consecutive winning zone, consecutive_normal D, consecutive_normal E, and consecutive_normal F are likely to be selected as map types. For consecutive_normal D, consecutive_normal E, and consecutive_normal F, the expected value of winning the pseudo bonus is higher in the first block than in the second block of the consecutive winning zone section (see FIG. 58). In this way, if the remaining period (number of games) of the advantageous section is less than the predetermined period, by determining table G, you can win the pseudo bonus relatively earlier than by determining table F. There is. As a result, it is possible to shorten the continuous zone section (section where medals decrease) between the pseudo-bonus section where medals increase and the pseudo-bonus section (section where medals decrease), and the dissatisfaction felt by the player can be resolved.

As described above, table H is determined when the type of pseudo bonus is "freeze". As shown in FIG. 87, in the case of table H in the consecutive winning zone, consecutive_quickly strong precursor B and consecutive_quickly strong precursor C are selected as the map types. Therefore, when the type of pseudo bonus is "freeze", the map type of the subsequent consecutive winning zone section is Ren_Soku-strong portent B or Ren_Soku-strong portent C. Further, Table I is determined when the mode is a special mode, which will be described later. As shown in FIG. 88, in the case of table I in the consecutive zone, the map type is determined to be consecutive_special. Therefore, in the case of special mode, ren_special wins.

[AT lottery (pseudo bonus lottery)]
Next, the AT lottery related to the second gaming machine will be explained. The second gaming machine is provided with three types of AT lottery: an AT lottery when the forced precursor G number is reached, a normal AT lottery, and an AT lottery when AT points are reached. Further, in the second gaming machine, when the winning combination is "middle-tier cherry", the winning of the pseudo bonus (AT) is determined without performing the AT lottery. As described above, "Cherry in the middle" is a determined hand, and corresponds to the above-mentioned "F_Nakadan Che 1" and "F_Nakadan Che 2".

(AT lottery when forced precursor G number is reached)
The AT lottery when the forced precursor G number is reached can be executed in the high probability zone, BIG certainty zone, and consecutive chance zone sections of the advantageous section. In the second gaming machine, it is determined whether or not to perform a forced precursor G number lottery at the 1st G of each block (50 G increments) in the high probability zone, BIG certain zone, and continuous chance zone section. In the block of MAP level 0, it is determined whether or not to perform the forced precursor G number lottery by the forced precursor entry lottery when the MAP level is 0. Further, in blocks of MAP levels 1 to 3, MAP level 5, and MAP level 6, it is decided to perform a forced precursor G number lottery. In the block of MAP level 4, it is determined that the forced precursor G number lottery is not performed.

The forced portent G number determined by the forced portent G number lottery is set in the forced portent game number counter. The forced precursor game number counter is decremented by 1 for each game, and in a game where the value of the forced precursor game number counter becomes "0", an AT lottery is performed when the forced precursor G number is reached. In the AT lottery when the forced precursor G number is reached, one of non-winning, fake winning, and real precursor winning is determined. If a non-winning is determined, no foreshadowing is performed.

When a fake win is determined, the number of fake omen games is determined, and the fake omen performance is performed over the determined number of fake omen games. In the final game of the fake omen performance, the main display device 210 etc. informs that the pseudo bonus (AT) has not been won. Furthermore, in a game in which a fake omen performance is performed, an AT lottery during a fake omen is performed. In the fake omen AT lottery, it is determined whether or not to change the fake winning to the real omen winning. Note that when changing a fake winning to a real omen winning, "BIG bonus" is determined as the type of pseudo bonus (AT). In addition, when changing a fake winning to a real omen winning, either make the remaining number of fake omen games the number of real omen games, or add an appropriate number of games to the remaining number of fake omen games to make the number of real omen games. It is determined whether or not. Then, the main omen performance is performed over the number of main omen games.

When the real omen lottery is determined, an AT type lottery is performed. In the AT type lottery, one of "REG bonus", "BIG bonus", "super big bonus", and "freeze" is determined. If "REG Bonus", "BIG Bonus", or "Super BIG Bonus" is determined by AT type lottery, the number of main precursor games is determined, and the main precursor effect is performed over the determined number of main precursor games. . On the other hand, if "Freeze" is determined by the AT type lottery, the main display effect is not performed, and in the next game, the main display device 210 etc. informs that the player has won the "Super BIG Bonus".

In the game in which the main omen performance is performed, a lottery for AT type promotion during the main omen is performed. In this omen AT type promotion lottery, it is determined whether or not to promote the "REG bonus" to the "BIG bonus" or whether to promote the "BIG bonus" to the "super BIG bonus". If the "Super BIG Bonus" is determined in the AT type lottery, the AT type promotion lottery during this omen will not be performed. In the final game of this omen performance, the type of the won (finally determined) pseudo bonus (AT) is notified by the main display device 210 or the like.

(Normal AT lottery)
Normal AT lottery is performed in a non-advantageous section and an advantageous section. In the non-advantageous section, the winning combinations that can be transferred to the advantageous section ("Unfair (only during RB/BB)", "F_Normal Rip 2", "F_Normal Rip 3", "1 in F_RB", and "F_RB If a winning combination other than "Middle Bell" is determined, a normal AT lottery is performed. On the other hand, in the advantageous section, normal AT lottery is performed during non-precursive periods. In normal AT lottery, either non-winning or winning is determined. The flow of the game when a winning is determined by the normal AT lottery is the same as when the above-mentioned true omen winning is determined. On the other hand, if a non-win is determined by the normal AT lottery, the pseudo bonus is not won and a fake omen entry lottery is performed. In the fake omen entry lottery, either a non-win or a win is determined. If a non-winning lottery is determined by the fake omen entry lottery, the fake omen performance will not be performed. The flow of the game when a win is determined by the fake precursor lottery is the same as when the above-described fake win is determined.

(AT lottery when AT points are reached)
In the second gaming machine, in a game where any one of "F_RB 1 piece 01" to "F_RB 1 piece 12" is won in the advantageous section and inside the RB, a stop is made to avoid displaying the combination of symbols related to "RB". The operation mode (order of correct answer presses) is notified. Then, when a stop operation is performed in an avoidance stop operation mode, symbol combinations related to "F_RB 1 piece 01" to "F_RB 1 piece 12" are displayed. Furthermore, if any one of "F_RB 1 piece 01" to "F_RB 1 piece 12" is won, 1 point is given as an AT point. It will be added to the AT point counter provided. Then, when the value of the AT point counter reaches a predetermined value (12 points in this embodiment), an AT lottery is performed when the AT point is reached. To explain in detail, after the next game in which the value of the AT point counter reaches a predetermined value, the game is not in the continuous zone zone, is in the non-precursor period, and is inside other than "F_RB 1 piece 01" to "F_RB 1 piece 12". When a winning combination is won, an AT lottery is performed when AT points are reached. At this time, if the value of the AT point counter is larger than a predetermined value, the predetermined value is subtracted from the value of the AT point counter, and the remaining points are carried over. In the AT lottery when AT points are reached, either non-winning or winning is determined. The flow of the game when a winning is determined by the AT lottery when AT points are reached is the same as when the above-mentioned main omen winning is determined. On the other hand, when a non-win is determined by the normal AT lottery, the pseudo bonus is not won, the number of fake precursor games is determined, and the fake precursor performance is performed over the determined number of fake precursor games. Further, the AT point counter is reset at the time of transition to a non-advantageous section. Note that the AT point counter may be reset at the time of winning or ending the "BIG bonus" and "super BIG bonus".

[Forced portent entrance lottery table at MAP level 0]
Next, with reference to FIG. 89, the MAP level 0 forced precursor entry lottery table will be described. The forced portent entry lottery table at MAP level 0 is the forced portent entry at MAP level 0, which is performed when the 1st G of each block (50G increments) in the high probability zone, BIG certain zone, and continuous zone section is MAP level 0. It is referred to for lottery, and defines lottery value information regarding winning/non-winning lottery results for each set value. Note that the probability denominator of the lottery value shown in FIG. 89 is "256".

[Forced portent game number lottery table]
Next, with reference to FIG. 90, the forced portent game number lottery table will be described. The forced portent game number lottery table is referenced to determine the number of forced portent games in the 1st G of each block (in 50G increments) in the high probability zone, BIG certain zone, and consecutive chance zone sections, and the forced portent game number lottery table is used to determine the number of forced portent games for each set value. Specifies the information on the lottery value regarding the number lottery result. Note that the probability denominator of the lottery value shown in FIG. 90 is "256".

[AT lottery table when the number of forced portent games is reached]
Next, the AT lottery table when the number of forced precursor games is reached will be explained with reference to FIGS. 91 to 97. The AT lottery table when the number of forced precursor games is reached is referred to for the AT lottery when the number of forced precursor games is reached, which is performed in the game where the value of the forced precursor games counter becomes "0". Information on the lottery value regarding the lottery results of the winning lottery and the omen winning lottery is specified. Note that the probability denominator of the lottery values shown in FIGS. 91 to 97 is "256".

FIG. 91 is an AT lottery table when the number of forced precursor games is reached, which is referred to when the MAP level is 0. As shown in FIG. 91, in the AT lottery when the number of forced portent games is reached when the MAP level is 0, the main portent winning is likely to be determined. That is, when it is determined that the forced portent game number lottery is to be performed by the forced portent entry lottery at the time of MAP level 0 when the MAP level is 0, the actual portent winning is likely to be determined. FIG. 92 is an AT lottery table when the number of forced precursor games is reached, which is referred to when the MAP level is 1. In the AT lottery when the number of forced portent games is reached when the MAP level is 1, a fake lottery is likely to be determined. FIG. 93 is an AT lottery table when the number of forced precursor games is reached, which is referred to when the MAP level is 2. In the AT lottery when the number of forced portent games is reached when the MAP level is 2, the actual portent winning is more likely to be determined than when the MAP level is 1.

FIG. 94 is an AT lottery table when the number of forced precursor games is reached, which is referred to when the MAP level is 3. In the AT lottery when the number of forced portent games is reached in the case of MAP level 3, the main portent winning is determined. Therefore, as shown in FIG. 58, when a map type in which MAP level 3 is defined is determined, a pseudo bonus (AT) is always won (determined). FIG. 95 is an AT lottery table when the number of forced precursor games is reached, which is referred to when the MAP level is 4. In the AT lottery when the number of forced portent games is reached when the MAP level is 4, a non-winning lottery is determined. Note that when the MAP level is 4, the forced precursor game number lottery is not performed, so basically the AT lottery when the forced precursor game number is reached is not performed.

FIG. 96 is an AT lottery table when the number of forced precursor games is reached, which is referred to when the MAP level is 5. In the AT lottery when the number of forced portent games is reached when the MAP level is 5, a non-winning lottery is determined. As shown in FIG. 58, when a map type in which MAP level 5 is defined is determined, a pseudo bonus (AT) is always won (determined). In this embodiment, in the AT lottery when the number of forced precursor games is reached when the MAP level is 5, the pseudo bonus is not won, but in the normal AT lottery, the pseudo bonus (AT) is always won. FIG. 97 is an AT lottery table when the number of forced precursor games is reached, which is referred to when the MAP level is 6. In the AT lottery when the number of forced portent games is reached when the MAP level is 6, a fake lottery is determined.

[Normal AT lottery table]
Next, the normal AT lottery table will be explained with reference to FIGS. 98 to 105. The normal AT lottery table is referred to for the normal AT lottery performed in the non-foreshadowing game, and defines information on winning combinations and lottery values for winning and non-winning lottery results for each set value. Note that the probability denominator of the lottery values shown in FIGS. 98 to 105 is "256". In addition, "Replay" of the winning combination shown in Figure 98 and thereafter corresponds to "F_Normal Reply 1" to "F_Normal Reply 3", and "RB1" corresponds to "F_RB1 piece 01" to "F_RB1 piece 12". handle. "Weak Che" corresponds to "F_Weak Che", and "Weak Watermelon" corresponds to "F_Weak Watermelon 1" and "F_Weak Watermelon 2". "Strong Che" corresponds to "F_Strong Che 1" and "F_Strong Che 2", and "Strong Watermelon" corresponds to "F_Strong Watermelon 1" and "F_Strong Watermelon 2".

FIG. 98 is a normal AT lottery table that is referred to when there is no table type (non-advantageous section). In the normal AT lottery when there is no table type, for example, when the winning combination is "Strong Che", a pseudo bonus (AT) is determined. FIG. 99 is a normal AT lottery table that is referred to when the MAP level is 0. In the normal AT lottery when the MAP level is 0, for example, when the winning combination is "Strong Che", a pseudo bonus (AT) is determined with a probability of about 1/10. FIG. 100 is a normal AT lottery table that is referred to when the map is at MAP level 1. In the normal AT lottery when the MAP level is 1, for example, when the winning combination is "Strong Che", a pseudo bonus (AT) is determined with a probability of about 1/3. FIG. 101 is a normal AT lottery table that is referred to when the map is at MAP level 2. In the normal AT lottery at MAP level 2, for example, when the winning combination is "Strong Che", a pseudo bonus (AT) is determined with a probability of about 3/4.

FIG. 102 is a normal AT lottery table that is referred to when the MAP level is 3. In the normal AT lottery at MAP level 3, for example, when the winning combination is "Strong Che", a pseudo bonus (AT) is determined with a probability of 255/256. FIG. 103 is a normal AT lottery table that is referred to when the map is at MAP level 4. In the normal AT lottery at MAP level 4, for example, a pseudo bonus (AT) is determined regardless of whether the winning combination is "Weak Che", "Weak Watermelon", "Strong Che", or "Strong Watermelon". be done. FIG. 104 is a normal AT lottery table that is referred to when the MAP level is 5. In the normal AT lottery at MAP level 5, a pseudo bonus (AT) is determined for any winning combination. FIG. 105 is a normal AT lottery table that is referred to when the MAP level is 6. In the normal AT lottery when the MAP level is 6, for example, when the winning combination is "Strong Che", a pseudo bonus (AT) is determined with a probability of 2/256.

[AT lottery table when AT points are reached]
Next, the AT lottery table when AT points are reached will be explained with reference to FIG. 106. The AT point lottery table is referred to for the AT point lottery, which is performed when the value of the AT point counter reaches a predetermined value (12 points in this embodiment), and records the winning combination and each set value. Information on lottery values regarding winning/non-winning lottery results is defined. Note that the probability denominator of the lottery value shown in FIG. 106 is "256".

[Fake omen AT lottery table]
Next, with reference to FIG. 107, the AT lottery table during fake precursor will be explained. The fake omen AT lottery table is referred to for the fake omen AT lottery performed in the game during the fake omen (fake omen is being performed), and it is used to determine the winning combination and the winning/non-winning lottery results for each set value. Specifies value information. Note that the probability denominator of the lottery value shown in FIG. 107 is "256". When a pseudo bonus is determined by AT lottery during fake omen, "BIG bonus" is determined as the type of pseudo bonus without performing AT type lottery.

[Lottery table for AT type promotion during Honmae]
Next, with reference to FIGS. 108 and 109, the AT type promotion lottery table during the present omen will be explained. The AT type promotion lottery table during this omen is referred to for the AT type promotion lottery during this omen (during the actual omen performance), and is used to determine the winning role and the winning/non-winning lottery for each set value. Specifies information about the lottery value for the result. Note that the probability denominator of the lottery values shown in FIGS. 108 and 109 is "256".

FIG. 108 is a real omen AT type promotion lottery table that is referred to when the type of the determined pseudo bonus is "REG bonus." FIG. 109 is an AT type promotion lottery table in the present omen that is referred to when the type of the determined pseudo bonus is "BIG bonus". As shown in FIGS. 108 and 109, promotion from "REG bonus" to "BIG bonus" is more easily determined than promotion from "BIG bonus" to "super BIG bonus."

[AT type lottery table]
Next, the AT type lottery table will be explained with reference to FIGS. 110 to 114. The AT type lottery table is referred to for the AT type lottery to be performed when a pseudo bonus (AT) prize is determined by various AT lotteries, and provides lottery value information regarding the lottery results of pseudo bonus types for each set value. stipulates. Note that the probability denominator of the lottery values shown in FIGS. 110 to 114 is "256".

FIG. 110 is an AT type lottery table that is referred to in the continuous zone section. As shown in FIG. 110, in the case of the continuous winning zone section, "REG bonus" is not determined as the pseudo bonus type, but "BIG bonus" or "super BIG bonus" is determined. FIG. 111 is an AT type lottery table that is referred to when the advantageous section is 201G or later. As shown in FIG. 111, in the case of the continuous winning zone section, "REG bonus" is not determined as the type of pseudo bonus. FIG. 112 is an AT type lottery table that is referred to when the special ON is on (special mode). As shown in FIG. 112, in the case of special ON (special mode), the "super BIG bonus" is not determined. FIG. 113 is an AT type lottery table that is referred to when the advantageous section is 1 to 100G. FIG. 114 is an AT type lottery table that is referred to when the advantageous section is 101 to 200G. As shown in FIGS. 113 and 114, in the advantageous section 1 to 100G, "REG bonus" and "BIG bonus" are determined with almost the same probability.

[AT type lottery table for middle cherry]
Next, with reference to FIGS. 115 and 116, the AT type lottery table for middle-tier cherry will be described. The middle-tier cherry AT type lottery table is referred to for the middle-tier cherry AT type lottery, which is performed when a pseudo bonus (AT) win is determined by winning a "middle-tier cherry," and determines the type of pseudo bonus for each set value. Specifies lottery value information regarding lottery results. Note that the probability denominator of the lottery values shown in FIGS. 115 and 116 is "256".

FIG. 115 is an AT type lottery table for middle cherry that is referred to when a "middle cherry" is won in a zone other than the consecutive winning zone (normal). FIG. 116 is a middle cherry AT type lottery table that is referred to when a "middle cherry" is won in the consecutive winning zone section. As shown in FIGS. 115 and 116, the "REG bonus" is not won in the AT type lottery at the time of middle cherry. In addition, if you win a "middle cherry" in a zone other than the consecutive zone (normal), there is a possibility that you will win a "freeze", but if you win a "middle cherry" in a consecutive zone zone ” does not win.

[Stable state (special mode)/Rough sea state (non-special mode)]
In the second gaming machine, a "stable state" and a "rough sea state" are provided as control states (which may also be referred to as a gaming state, mode, or internal state) in an advantageous section. The "stable state" is the above-mentioned "special mode ON", and although the possibility that the player will be able to rapidly increase the gaming value is reduced, the player's gaming value is unlikely to decrease. Further, the "rough sea state" is a "special mode OFF", and although there is a high possibility that the player will be able to rapidly increase the gaming value, the player's gaming value is likely to decrease. In addition, in the second gaming machine, a "stable state" and a "rough sea state" are provided as internal states, but the number of internal states is not limited to two, and may be three or more. . The internal states according to the present invention may include, for example, a "first stable state", a "second stable state", a "first rough sea state", and a "second rough sea state".

In the second gaming machine, a special rewritten lottery is performed in a game in which a fake sign (performance) of the fourth block (151G to 200G) is started. In the special rewriting lottery, it is determined whether or not to rewrite the fake omen to the real omen depending on whether the special mode is turned on or off. If it is in a "stable state" (special mode ON) at the time of special rewriting lottery, it is more likely to be rewritten to this omen than if it is in a "rough sea state" (special mode OFF). In addition, when performing a normal AT lottery in a "stable state" (special mode ON), if the MAP level at that time is "MAP level 1" or "MAP level 2", the normal AT lottery of "MAP level 6" Browse the table. Further, in the case of the "stable state" (special mode ON), the AT lottery during the fake sign is not performed. In addition, when it is in the "stable state" (special mode ON), "super big bonus" and "freeze" are not won in the AT type lottery (see FIG. 112). Furthermore, if the "BIG bonus" is determined as the type of pseudo bonus in the "stable state" (special mode ON), "Table I" is determined as the table type for the continuous winning zone section. Further, in the case of a "stable state" (special mode ON), forced precursor G number lottery is not performed at MAP level 0. That is, at MAP level 0, it is decided not to perform the forced precursor G number lottery at MAP level 0 (see FIG. 89) and not to perform the forced precursor G number lottery.

In the second gaming machine, a "stable state" (special mode ON) is set when transitioning to an advantageous section. Then, in the second gaming machine, if the game is in the normal section of the advantageous section, the gaming state is other than inside BB, and is not in the foreshadowing state, and the player wins "F_Weak Che", the Cherry Navi lottery is executed. conduct. In the Cherry Navi lottery, the winning or non-winning of Cherry Navi is determined depending on whether the special mode is turned on or off. If the Cherry Navi lottery is in a "stable state" (special mode ON), the winning of Cherry Navi is more likely to be determined than in the case of a "rough sea state" (special mode OFF). When the Cherry Navi lottery is determined to be a Cherry Navi lottery, information about a stop operation (for example, "27") is displayed on the instruction monitor, and a performance pattern different from the usual one is executed. At this time, a specific stop operation mode corresponding to the stop operation information displayed on the instruction monitor (for example, the order of the fourth reel D, third reel C, second reel B, first reel A, and the fourth reel When the press timing is such that a cherry is displayed on the lower row of reel D, "NM19" (C_weak Che A) is displayed and two medals are paid out. On the other hand, if a specific stop operation mode is not performed, "NM19" (C_Weak Chee A) is not displayed, and the combination of symbols that pays out one medal ("NM20" (S_Weak Chee B)) , or the display mode of missing items is displayed. In the second gaming machine, "NM19" (C_Weak Che A) is displayed, and when two medals are paid out, the "stable state" (special mode ON) is maintained, and "NM19" (C_ If weak game A) is not displayed and one medal is paid out, or if no medals are paid out, the mode is switched to a "rough sea state" (special mode OFF). In addition, in the second gaming machine, the state (mode) transition is determined by whether or not two medals are paid out, but "NM19" (C_Weak Che A) is displayed regardless of the number of medals. The state (mode) transition may be determined based on whether or not the current state (mode) occurs.

In this way, in the "stable state" (special mode ON), it is impossible to win "Super BIG Bonus" or "Freeze", but since it is easy to win the Cherry Navi, it is possible to win "F_Weak Che". If you do so, you will be able to earn two medals. Therefore, in the "stable state" (special mode ON), although it is less likely that the player will be able to rapidly increase the gaming value, the player's gaming value is unlikely to decrease. On the other hand, in "Rough Waves" (special mode OFF), it is possible to win "Super BIG Bonus" and "Freeze", but since it is difficult to determine the winnings of Cherry Navi, if you win "F_Weak Che", It is difficult to win two medals. Therefore, in the "rough sea state" (special mode OFF), although there is a high possibility that the player will be able to rapidly increase the gaming value, the player's gaming value is likely to decrease.

FIG. 117 is a diagram illustrating the performance pattern of the normal scroll performance (when there is no winning in the Cherry Navi lottery). Further, FIG. 118 is a diagram illustrating a performance pattern of a scroll performance when a winner is won in the Cherry Navi lottery. As shown in FIG. 117, when the normal (non-winning in Cherry Navi lottery) scroll performance pattern is executed, the scroll is displayed on the left end of the display screen of the main display device 210, and then moves toward the right end. By opening the scroll, a display indicating a winning combination is made. On the other hand, as shown in FIG. 117, when the performance pattern of the scroll performance at the time of winning in the Cherry Navi lottery is executed, the scroll is displayed on the right end of the display screen of the main display device 210, and then the scroll is displayed toward the left end. When opened, a display indicating a winning combination is displayed. Thereby, a specific stop operation mode is suggested by the effect using the main display device 210. If the player notices this suggestion or the display on the instruction monitor and wants to maintain the "stable state" (special mode ON), he performs a specific stopping operation to display "NM19" (C_Weak Che A). Also, if the player notices this suggestion or the display on the instruction monitor and wants to switch to the "rough sea state" (special mode OFF), "NM19" (C_Weak Che A) is displayed without performing a specific stop operation mode. I won't let you. Further, it is preferable that the specific stop operation mode is different from the stop operation mode normally performed by the player. As a result, if the player does not notice the suggestion by the main display device 210 or the display on the instruction monitor, it is possible to switch to the "rough sea state" (special mode OFF).

In addition, as for the second gaming machine, when "F_Weak Che" is won, "NM19" (C_Weak Che A) is displayed and two medals are paid out, and in the next game, "Stable state" is displayed. ” (special mode ON). However, in the gaming machine of the present invention, winning in the Cherry Navi lottery may be added to the conditions for performing the process of transitioning to the "stable state" (special mode ON). In other words, the internal state may be made transferable when a win is determined in the Cherry Navi lottery. As a result, when the normal (non-winning in Cherry Navi lottery) scroll performance pattern is executed, even if a specific stop operation is performed and "NM19" (C_Weak Che A) is displayed, " It is possible to prevent the system from shifting to the "stable state" (special mode ON). As a result, it becomes difficult to shift to the "stable state" (special mode ON), and the "stable state" (special mode ON) can become rare.

FIG. 119 is a simplified diagram for explaining the timing of the conventional state (mode) transition process and the timing of the state (mode) transition process of the second gaming machine (the present invention). For example, suppose that in the process for the 1st lever shown in FIG. 119, the player wins "F_weak check". In the conventional process when all the reels of the 1st G are stopped, the number of medals to be paid out is detected, and if "NM19" (C_Weak Che A) is displayed and two medals have been paid out, a flag related to the special mode is set. Turn it on. On the other hand, if "NM19" (C_Weak Che A) is not displayed and two medals have not been paid out, the flag related to the special mode is turned OFF (special mode OFF). Then, in the 2nd G lever processing, it is determined whether the flag related to the special mode is ON or not, and if the flag related to the special mode is ON, the transition processing to the "stable state" (special mode ON) is performed. will be held. On the other hand, if the flag related to the special mode is OFF, a transition process to a "rough sea state" (special mode OFF) is performed.

In the process when all the reels of the 1st G in the second gaming machine are stopped, the flag related to the special mode is not turned on or off. Then, in the lever processing of the 2nd G, if the winning combination of the 1st G (previous) is "F_Weak Che", the number of medals paid out is detected, and if 2 medals have been paid out, the special mode is activated. This flag is turned ON and a transition process to a "stable state" (special mode ON) is performed. On the other hand, if two medals have not been paid out, the flag related to the special mode is turned OFF, and a transition process to a "rough sea state" (special mode OFF) is performed. This makes it possible to reduce the number of determination processes and improve the efficiency of state (mode) transition processing.

Further, in the second gaming machine, a pseudo bonus (AT) is drawn after the state (mode) transition process. For example, in the case of "rough sea conditions" (special mode OFF) and "MAP level 1", you will win the Cherry Navi lottery, "NM19" (C_Weak Che A) will be displayed, and 2 medals will be paid out. Suppose that After a transition to a "stable state" (special mode ON) is made in the lever processing of the next game, a pseudo bonus (AT) is drawn. As mentioned above, when performing a normal AT lottery in a "stable state" (special mode ON), if the MAP level at that time is "MAP level 1" or "MAP level 2", the "MAP level 6" Normally, the AT lottery table is referred to. Therefore, since the current MAP level is "MAP level 1", when performing the normal AT lottery, the pseudo bonus (AT) lottery is performed with reference to the normal AT lottery table of "MAP level 6". Incidentally, a pseudo bonus (AT) may be randomly selected before the state (mode) transition process. For example, in the case of "rough sea conditions" (special mode OFF) and "MAP level 1", you will win the Cherry Navi lottery, "NM19" (C_Weak Che A) will be displayed, and 2 medals will be paid out. Suppose that When performing a normal AT lottery in the lever processing of the next game, after the pseudo bonus (AT) lottery is performed by referring to the normal AT lottery table of "MAP level 1", the "stable state" (special mode ON).

Note that reducing the process of determining the number of medals to be paid out when the reels are all stopped, and detecting the number of medals to be paid out at the next lever and executing the process is not limited to state transition processing, but can be done as in the following modification example. It can be used even in such cases.

(Modification 1)
During the non-foreshadowing period of the normal section, in the game following the game in which "F_weak Che" was won, it is detected whether two medals were paid out in the game in which "F_weak Che" was won, and the normal AT lottery Make the table change. In the game following the game in which "F_Weak Che" was won, if it is detected that two medals were paid out in the game in which "F_Weak Che" was won, the MAP level is other than "MAP level 5". In this case, the normal AT lottery is performed by referring to the normal AT lottery table of "MAP level 5", and if the MAP level is "MAP level 5", the normal AT lottery of "MAP level 5" is performed without being changed. A normal AT lottery is performed by referring to an AT lottery table. Note that the normal AT lottery may be performed by referring to the normal AT lottery table not only for "MAP level 5" but also for "MAP level 3" or "MAP level 4". In addition, in the next game after the game in which "F_Weak Che" was won, if it is detected that two medals were not paid out in the game in which "F_Weak Che" was won, the "MAP Level 6" normal A normal AT lottery is performed by referring to an AT lottery table.

In addition, in the game following the game in which "F_Weak Che" was won, if it is detected that two or one medal was paid out in the game in which "F_Weak Che" was won, the "MAP Level 5" Normal AT lottery is performed by referring to the normal AT lottery table, and if it is detected that no medals were paid out (missed) in the game where "F_weak Che" was won, the normal AT lottery of "MAP level 6" is performed. A normal AT lottery may be performed by referring to a table.

(Modification 2)
In the game following the game in which "F_Weak Che" was won, it is detected whether two medals were paid out in the game in which "F_Weak Che" was won, and whether or not the pseudo bonus (AT) was won. Decide whether or not to perform the inciting performance. When it is detected that two medals are paid out in the game in which "F_weak che" is won in the game following the game in which "F_weak che" is won, an inciting effect is executed on the main display device 210. In addition, in the next game after the game in which "F_Weak Che" was won, if it is detected that two medals were not paid out in the game in which "F_Weak Che" was won, the main display device 210 displays an inciting effect. do not execute.

In addition, in the game following the game in which "F_Weak Che" was won, if it is detected that two or one medal was paid out in the game in which "F_Weak Che" was won, the main display device 210 will display a warning message. If the effect is executed and it is detected that no medals were paid out (missed) in a game in which "F_Weak Che" was won, the main display device 210 may not execute the inciting effect.

Further, the inciting effect is not limited to the effect by the main display device 210, but may be an effect by the speakers 35a, 35b, the upper lamp 23, etc. For example, in the next game after the game in which "F_Weak Che" was won, if it is detected that two medals were paid out in the game in which "F_Weak Che" was won, a special start sound different from the normal start sound If it is detected that two medals were not paid out in a game in which "F_Weak Che" was won, a normal start sound may be played.

In addition, in the game following the game in which "F_Weak Che" was won, if it is detected that two or one medal was paid out in the game in which "F_Weak Che" was won, a special start sound is played. , when it is detected that no medals were paid out (missed) in a game in which the player won "F_Weak Che", a normal start sound may be played.

(Modification 3)
During the "BIG Bonus", the probability of winning 1G consecutive varies depending on the internal winning combination, and if you win "Strong Che"("F_Strong Che 1" or "F_Strong Che 2"), it is 64/256, If you win "RB1 piece"("F_RB1 piece 01" to "F_RB1 piece 12"), you will win 1G consecutive with a probability of 1/256, and if you win any other internal winning combination, you will win 1G series.

In the game following the game in which "F_Weak Che" is won, it is detected whether two medals are paid out in the game in which "F_Weak Che" is won, and the probability of winning 1G series is changed. In the game following the game in which "F_Weak Che" was won, if it is detected that two medals were paid out in the game in which "F_Weak Che" was won, the 1G series will be won regardless of the internal winning combination. Change the probability to 128/256. Note that the probability of winning the 1G series may be changed to 256/256 regardless of the internal winning combination. In addition, in the next game after the game in which "F_Weak Che" was won, if it is detected that two medals were not paid out in the game in which "F_Weak Che" was won, 1G will be awarded regardless of the internal winning combination. Change the probability of winning the series to 0/256. In addition, in the next game after the game in which "F_weak Che" was won, if it is detected that two medals were not paid out in the game in which "F_weak Che" was won, the probability of winning 1G consecutive is calculated. You may choose not to change it.

In addition, in the game following the game in which "F_Weak Che" was won, if it is detected that 2 or 1 medal was paid out in the game in which "F_Weak Che" was won, regardless of the internal winning combination. The probability of winning 1G series is changed to 128/256, and if it is detected that no medals were paid out (missed) in a game where "F_weak Che" was won, the probability of winning 1G series will be changed regardless of the internal winning combination. The probability of doing so may be changed to 0/256. Note that when it is detected that no medals were paid out (missed) in a game in which the "F_Weak Che" was won, the probability of winning the 1G series may not be changed.

[Special rewritten lottery table]
Next, the special rewriting lottery table will be explained with reference to FIGS. 120 and 121. The special rewritten lottery table is referred to for the special rewritten lottery performed in the game where the fake omen (performance) of the fourth block (151G to 200G) is started, and is used to determine the winning and non-winning lottery results for each set value. Specifies value information. Note that the probability denominator of the lottery values shown in FIGS. 120 and 121 is "256".

FIG. 120 is a special rewriting lottery table that is referred to when the special mode is OFF. As shown in FIG. 120, when the special mode is OFF, the winning of the special rewriting lottery is almost never determined. Therefore, when the special mode is OFF, even if a fake omen (performance) is performed in the fourth block, it is difficult to rewrite to the real omen by special rewriting lottery. Note that when the special mode is OFF, an AT lottery during a fake sign is performed. Note that when the special mode is OFF, the probability of winning the special rewriting lottery is 1/256 regardless of the setting value, but it may be set to 0/256 regardless of the setting value. Further, the probability of winning the special rewriting lottery may be changed depending on the set value. FIG. 121 is a special rewriting lottery table that is referred to when the special mode is ON. As shown in FIG. 121, when the special mode is ON, the winning of the special rewriting lottery is almost determined. Therefore, when the special mode is ON, if a fake omen (effect) is performed in the fourth block, it is likely to be rewritten to a real omen by special rewriting lottery. Note that when the special mode is OFF, the AT lottery during fake sign is not performed. Note that when the special mode is ON, the probability of not winning the special rewriting lottery is 1/256 regardless of the setting value, but it may be set to 0/256 regardless of the setting value. Further, the probability of winning (not winning) the special rewriting lottery may be changed depending on the set value.

[Cherry Navi lottery table]
Next, the CherryNavi lottery table will be explained with reference to FIGS. 122 and 123. The Cherry Navi lottery table is for the Cherry Navi lottery that is performed in the normal section of the advantageous section, and the gaming state is other than BB inside, and is not in the foreshadowing mode, and when the winner is "F_Weak Che". This is referred to and defines lottery value information regarding winning/non-winning lottery results for each set value. Note that the probability denominator of the lottery values shown in FIGS. 122 and 123 is "256".

FIG. 122 is a Cherry Navi lottery table that is referred to when the special mode is OFF. As shown in FIG. 122, when the special mode is OFF, the winning of the Cherry Navi lottery is almost never determined. Therefore, when the special mode is OFF, it is difficult to display stop operation information on the instruction monitor, and it is difficult to perform an effect suggesting a specific stop operation mode (see FIG. 118). Note that when the special mode is OFF, the probability of winning the Cherry Navi lottery is 1/256 regardless of the setting value, but it may be set to 0/256 regardless of the setting value. Furthermore, the probability of winning the Cherry Navi lottery may be changed depending on the set value. FIG. 123 is a Cherry Navi lottery table that is referred to when the special mode is ON. As shown in FIG. 123, when the special mode is ON, the winning of the Cherry Navi lottery is almost determined. Therefore, when the special mode is ON, information about a stop operation is likely to be displayed on the instruction monitor, and an effect suggesting a specific stop operation mode is likely to be performed (see FIG. 118). Note that when the special mode is ON, the probability of not winning the Cherry Navi lottery is 1/256 regardless of the setting value, but it may be set to 0/256 regardless of the setting value. Furthermore, the probability of winning (not winning) the Cherry Navi lottery may be changed depending on the set value.

[Table determination when moving to advantageous section]
As described above, the second gaming machine determines the table type to be used in the normal section in the next game after transition to the advantageous section. Then, the map type is determined according to the table type. Further, the map type defines the MAP level in each block, and in the AT (pseudo bonus) lottery in the normal section, winning or non-winning is determined according to the MAP level and the winning combination. Therefore, determining the table type in the next game after transition to the advantageous section affects the subsequent AT (pseudo bonus) lottery.

In the next game after transition to the advantageous section, when determining the table type to be used in the normal section, the type of RT state at that time is referred to. There are four types of RT states: RT0 state to RT3 state (FIG. 38). The RT0 state is set when initialization is performed by a setting change operation, and the RT1 state is transitioned to when the bonus (RB, BB) operation is completed. The RT2 state is entered when the bonus (RB, BB) is in progress, and the RT3 state is entered when the bonus (RB, BB) is in operation. In the next game after transition to the advantageous section, if the RT state is the RT0 state, table A is not determined, but tables B to E are determined. The normal section when table A has been determined has a lower expectation level for determining a pseudo bonus than the normal section when tables B to E have been determined. Therefore, it is a privilege for the player that table A is not determined (tables B to E are determined). Note that in the RB1 state and the RB2 state, there is a possibility that table A will be determined, and the probability that table A will be determined is higher than the probability that tables B to E will be determined.

In this way, in the second gaming machine, if it is possible to shift from the non-advantageous section to the advantageous section (in RT0 state) before winning the bonus (RB, BB), the lottery will be more advantageous than table A. Tables B to E are determined. On the other hand, when the bonus (RB, BB) operation ends, the state is shifted to RT1. Therefore, even if you intentionally win and activate the bonus (RB, BB) just before the end of the advantageous section, the RT state cannot be transferred to the RT0 state. As a result, it is possible to prevent the player from receiving a benefit (advantageous lottery) by intentionally changing the gaming state. The benefits according to the present invention are not limited to receiving an advantageous lottery, but include, for example, transitioning to a predetermined state (for example, CZ (chance zone) where the expected value of AT winning is high), AT (pseudo This can be set as appropriate, such as increasing the number of games (bonus).

In the second gaming machine, "RB" is "F_Weak Che", "F_Strong Che 1", "F_Strong Che 2", "F_Weak Watermelon 1", "F_Weak Watermelon 2", "F_Strong Watermelon". 1'', ``F_Strong Watermelon 2'', and ``F_Batting Order BB01'' to ``F_Batting Order BB10''. In this case, regardless of the stop operation mode, "F_Weak Che", "F_Strong Che 1", "F_Strong Che 2", "F_Weak Watermelon 1", "F_Weak Watermelon 2", "F_Strong Watermelon 1" ”, “F_strong watermelon 2”, and symbol combinations related to “F_batting order BB01” to “F_batting order BB10” are displayed, and symbol combinations related to “RB” are not displayed (see FIG. 45). Thereby, winning of "RB" can be easily avoided.

In the second gaming machine, if "F_RB1 piece 01" to "F_RB1 piece 12" are won in the RB, if the stop operation is performed in the correct order of pressing, "F_RB1 piece 01" to "F_RB1 piece 12" is won. ” is displayed (see FIG. 47). On the other hand, if the stop operation is not performed in the correct pressing order, a symbol combination related to "RB" may be displayed depending on the timing of the stop operation. Therefore, in the second gaming machine, when "F_RB 1 piece 01" to "F_RB 1 piece 12" are won within the RB and during the advantageous section, the main display device 210 or the like notifies the correct pressing order. This makes it possible to maintain the RB internal state (carryover).

In the second gaming machine, when the RT state in the next game after transition to the advantageous section is the RT0 state, the table type is determined regardless of the setting value (see FIG. 54). As a result, in the RT0 state, Tables B to E can be determined without being influenced by the setting values, and it is possible to prevent the granting of benefits from becoming equal. Further, in the second gaming machine, if the RT state in the next game after transition to the advantageous section is other than the RT0 state (RT1 state, RT2 state), the table type is determined according to the set value (see FIG. 55). As a result, in cases other than the RT0 state (RT1 state, RT2 state), the probability that tables A to E will be determined can be varied according to the setting value, and the determined table type can be predicted from the gaming state. It can be made difficult to do.

[Processing that refers to the number of coins to be paid out]
In the second game, when the reels 3A to 3D all stop in a game in which "F_Weak Che" is won, the flag related to the special mode is not turned on or off. Then, in the next game after the game in which "F_Weak Che" was won, it is determined whether or not two medals were paid out in the previous game, and if two medals were paid out, a special A flag related to the mode is turned ON, and a transition process to a "stable state" (special mode ON) is performed. On the other hand, if two medals have not been paid out, the flag related to the special mode is turned OFF, and a transition process to a "rough sea state" (special mode OFF) is performed. As a result, it is possible to reduce the conventional process of determining whether the flag related to the special mode is ON, and to reduce the process of determining whether or not the flag related to the special mode is ON, and the process of determining in a game where "F_Weak Che" is won. As a result, it is possible to improve the efficiency of state (mode) transition processing.

If you win "F_Weak Che", a specific stop operation mode (for example, the order of 4th reel D, 3rd reel C, 2nd reel B, 1st reel A, and the lower row of 4th reel D) If it is the pressing timing when a cherry is displayed), "NM19" (C_Weak Che A) is displayed and two medals are paid out. Further, if a specific stop operation mode is not performed, "NM20" (S_weak CheB) is displayed and one medal is paid out, or a display mode indicating that the medal has been missed is displayed. Thereby, it is possible to select the state (mode) to be transitioned to depending on the stop operation mode. Furthermore, the ease with which medals are reduced can be varied depending on the stopping operation mode. Further, in the second gaming machine, when a specific stop operation mode is not performed, "NM20" (S_Weak Che B) can be displayed. Therefore, by checking whether the display mode is "NM19" (C_Weak Che A) or "NM20" (S_Weak Che B), it is possible to make the player recognize the state (mode) transition destination. can.

In the second gaming machine, when the transition process to the "stable state" (special mode ON) is performed, the normal AT lottery table of MAP level 6 is referred to, and the pseudo bonus winning rate becomes "extremely low." Therefore, by performing transition processing to a "stable state" (special mode ON) and "rough sea state" (special mode OFF), the probability of transition to AT (pseudo bonus) can be varied, and AT ( It is possible to make the transition lottery to a pseudo bonus) various. Further, in the second gaming machine, when a Cherry Navi winning is determined by the Cherry Navi lottery, information on a stop operation (for example, "27") is displayed on the instruction monitor. Thereby, it is possible to indicate that the player has won "F_Weak Che" using the display on the instruction monitor. Further, in the second gaming machine, when a Cherry Navi winning is determined by the Cherry Navi lottery, the performance mode (performance pattern) of the scroll performance is changed to a different performance mode from the usual one. As a result, it is possible to indicate that the player has won "F_Weak Che" in a presentation mode different from the usual scroll presentation.

In the second gaming machine, the probability that a Cherry Navi win is determined by Cherry Navi lottery in a "stable state" (special mode ON) is the same as the probability that a Cherry Navi win is determined by Cherry Navi lottery in a "rough sea state" (special mode OFF). is higher than the probability that is determined (see FIGS. 122 and 123). As a result, when in a "stable state" (special mode ON), it is easier to suggest that "F_weak check" has been determined, and it is easier to maintain a "stable state" (special mode ON). becomes easier. On the other hand, in the case of "rough sea conditions" (special mode OFF), it is difficult to suggest that "F_weak check" has been determined, and from "rough sea conditions" (special mode OFF) to "stable state" ( (special mode ON) becomes difficult. Furthermore, in the second gaming machine, the "rough sea state" (special mode OFF) is given preferential treatment in the lottery for transition to a pseudo bonus (AT) than the "stable state" (special mode ON). Thereby, the "rough sea state" (special mode OFF) can be made into a state in which the player's medals are likely to decrease, although there is a high possibility that the medals can be increased.

The transition process to the "stable state" (special mode ON) in the second gaming machine corresponds to the first process according to the present invention, and the transition process to the "rough sea state" (special mode OFF) corresponds to the first process according to the present invention. This corresponds to the second processing. However, the first process and the second process according to the present invention are not limited to the transition process to a "stable state" and a "rough sea state". The first process and the second process according to the present invention can be set as appropriate as long as it is a main process that controls the game. AT lottery, etc.), a process of giving points related to a game, a process of changing management information (for example, tables A to E) or advantage information (for example, map type). In addition, the second gaming machine performs processing both when two medals are paid out and when two medals are not paid out in a game where "F_weak Che" is won. I made it. However, the gaming machine of the present invention may perform main processing for controlling the game in the case of one determination result, and may not perform the main processing for controlling the game in the case of the other determination result.

[Number of games remaining in advantageous section and table determination]
In the second gaming machine, table F to be used in the continuous winning zone section is determined when the remaining period (number of games) of the advantageous section is equal to or longer than a predetermined period. On the other hand, table G is determined when the remaining period (number of games) of the advantageous section is less than a predetermined period. As shown in FIGS. 85 and 86, in the consecutive zone map lottery, for example, "ren_normal D" and "ren_normal D" have a higher expectation of transition to a pseudo bonus (AT) than "ren_normal D". It is possible to win "Normal F". When table G is determined in the continuous zone section, "continuous_normal F" is more likely to be determined than when table F is determined. Therefore, when table G has been determined, it is easier to win (transfer to) the pseudo bonus sooner than when table F has been determined. If the remaining period (number of games) of the advantageous section is less than a predetermined period, by determining table G, the pseudo bonus is won relatively earlier than when determining table F. As a result, it is possible to shorten the continuous zone section (section where medals decrease) between the pseudo-bonus section where medals increase and the pseudo-bonus section (section where medals decrease), and the dissatisfaction felt by the player can be resolved.

In the second gaming machine, when "BIG bonus", "super big bonus", or "freeze" is determined as the type of pseudo bonus, the table used in the consecutive chance zone section that starts after the end of the pseudo bonus section is Decide on the type. As a result, the type of table used in the consecutive zone zone is determined before the consecutive zone zone starts. As a result, management information can be used from the first game in the continuous zone section. Further, in the second gaming machine, the map type is determined in accordance with the table type in the continuous change zone section. The map type defines the MAP level in each block. In the AT (pseudo-bonus) lottery in the continuous chance zone section, a winner or a non-winner is determined according to the MAP level and the winning combination. Thereby, it is possible to make the transition lottery to the pseudo bonus (AT) in the continuous chance zone section various. Further, in the second gaming machine, since the degree of expectation of transition to a pseudo bonus (AT) differs depending on the map type, it is possible to increase the interest of the game by varying the degree of expectation of transition.

In the second gaming machine, the probability that a map type (for example, "Run_Normal F") with a high expectation of transition to a pseudo bonus (AT) will be determined differs depending on the setting value. Thereby, it is possible to vary the degree of expectation of transition to a pseudo bonus (AT) according to the set value, and it is possible to improve the interest of the game.

[Additional note 1]
In a conventional gaming machine, a non-advantageous section and an advantageous section can be set, and an AT state can be set in the advantageous section, and when a predetermined end condition is met, the gaming machine shifts from the advantageous section to the non-advantageous section. is known (for example, see Japanese Unexamined Patent Publication No. 2017-185099).

Among these gaming machines, when transitioning from a non-advantageous section to an advantageous section, it is determined whether or not an advantageous lottery can be received depending on whether the gaming state is within bonus or general. . For example, if the bonus flag is initialized at the time of setting change and it is possible to shift from a non-advantageous section to an advantageous section before winning a bonus, it is possible to receive an advantageous lottery. However, by intentionally winning a bonus just before the end of the advantageous section, burning out the bonus and changing the gaming state to normal, and then moving to the advantageous section, you can receive an advantageous lottery even when the settings are not changed. The problem arises that the

The present invention has been made in view of these points, and provides a gaming machine that prevents players from intentionally winning a bonus just before the end of an advantageous section so as to receive an advantageous lottery (privilege). The purpose is to

internal winning combination determination means (for example, main CPU 101 that performs internal lottery processing) that determines an internal winning combination with a predetermined probability;
A variable display means (for example, reels 8A to 8D) that is composed of a plurality of display rows and displays symbols necessary for the game in a variable manner;
A stop operation detection means (for example, a stop switch 8S) that detects a stop operation by a player;
a stop control means (for example, a main CPU 101 that performs a reel stop control process) that stops the fluctuating display of the symbols based on the determination result of the internal winning combination determination means and the detection of a stop operation by the stop operation detection means;
Notifying means (for example, main display device 210) capable of notifying the player of a stop operation mode that is advantageous to the player;
A section control means (for example, a section control means for controlling the transition of a gaming state) between a non-advantageous section in which it is not possible to notify the stopping operation mode by the notifying means and an advantageous section in which it is possible to notify the stopping operation mode by the notifying means. a main CPU 101) that performs
The internal winning combination determination means is capable of determining a carryover special combination (for example, RB),
The types of gaming states include a first state in which the special prize is not carried over (for example, RT0 state), a second state in which the special prize is carried over (for example, RT2 state), and a symbol combination related to the special prize. A third state (for example, RT1 state) to which the special game is started after the derivation is started;
Privilege determining means (for example, not determining table A) for determining whether or not to provide a privilege (for example, not determining table A) according to the type of gaming state when a transition from the non-advantageous section to the advantageous section is determined; For example, a gaming machine further comprising a main CPU (101) that performs a table type lottery by referring to a table type lottery table (in RT0).
According to such a gaming machine, it is possible to receive a benefit (advantageous lottery) by intentionally winning a special winning combination (RB) just before the end of an advantageous section and changing the gaming state. It can be prevented. Further, it is possible to create a state in which a privilege is given to the player when it is determined to shift from a non-advantageous section to an advantageous section in a specific gaming state.

When the transition from the non-advantageous section to the advantageous section is determined, if the gaming state is the first state, the benefit is granted more than when the gaming state is the third state. The gaming machine described above is characterized by a high percentage of
According to such a gaming machine, even if you intentionally win a special winning combination (RB) just before the end of the advantageous section and change the gaming state to the third state, the benefit (advantageous The chances of winning a lottery (lottery) will be lower. Therefore, by intentionally changing the gaming state immediately before the end of the advantageous section, it is not possible to make the rate at which a benefit (advantageous lottery) can be received higher than in the first state. Furthermore, when it is determined in the first state to move from a non-advantageous section to an advantageous section, the rate at which benefits are given to the player can be made higher than in the third state.

The gaming machine described above is characterized in that the special winning combination can be won in combination with a specific winning combination (for example, "F_batting order BB01" to "F_batting order BB10").
According to such a gaming machine, in a game in which a special winning combination is won, it becomes possible to display a symbol combination related to a specific winning combination, and it is possible to easily create a second state in which the special winning combination is carried over.

Equipped with initialization means (for example, a setting key type switch 52 and a reset switch 53) capable of initializing predetermined game information (for example, data in a designated storage area),
The gaming machine described above is characterized in that the gaming state is not shifted to the first state until the predetermined gaming information is initialized by the initializing means.
According to such a gaming machine, when predetermined gaming information is initialized, it is possible to create a state in which a privilege is given to a player. Therefore, it is possible to prevent the granting of benefits from occurring frequently, and the value of the benefits can be increased.

The above-mentioned game is characterized by having a plurality of pieces of management information (e.g., tables A to E) for managing a decision as to whether or not to move to an advantageous state (e.g., pseudo-bonus (AT)) that is advantageous for the player. Machine.
According to such a gaming machine, the difficulty level of transitioning to an advantageous state can be varied.

comprising a management information determining means (for example, a main CPU 101 that performs table type lottery) that determines one management information from the plurality of management information,
The management information determining means determines the type of management information by referring to the type of the gaming state when a start operation for the next game that has transitioned from the non-advantageous section to the advantageous section is performed. The above gaming machines are characterized by:
According to such a gaming machine, determining the type of management information can be made to correspond to determining whether or not to grant a benefit.

The gaming machine described above is characterized in that the benefit is that predetermined management information (for example, table A) with a low expectation of transition to the advantageous state is not selected.
According to such a gaming machine, it is possible to vary the degree of expectation of transition to an advantageous state depending on the type of gaming state when a transition from a non-advantageous section to an advantageous section is determined, thereby increasing the interest in the game. can be increased.

When the type of management information is determined, advantage information determining means (for example, performing a normal map lottery) that determines advantage information (for example, map type) related to determining whether to shift to the advantageous state or not. The gaming machine described above is characterized by comprising a main CPU (101).
According to such a gaming machine, the degree of expectation of transition to an advantageous state can be varied.

The management information determining means determines the type of management information regardless of a set value indicating the degree of advantage of the player regarding the game, when it is determined to move to the advantageous section in the first state. The above-mentioned gaming machine is characterized by the following.
According to such a gaming machine, in the first state, it is possible to determine the type of management information that corresponds to the granting of benefits without being influenced by the setting value.

When it is determined in the second state or the third state to move to the advantageous section, the management information determining means determines the management information according to a set value indicating the degree of advantage of the player regarding the game. The gaming machine described above is characterized in that the type of gaming machine is determined.
According to such a gaming machine, when the game machine is in the second state or the third state, the probability that each piece of management information is determined can be varied according to the set value, and the type of determined management information can be changed. This can make it difficult to predict based on the gaming state.

[Additional note 2]
In conventional gaming machines, information advantageous to players is provided so that symbol combinations related to the winning combination determined as an internal winning combination are displayed, or so that symbol combinations related to the determined winning combination are not omitted. There are known devices equipped with an AT function that notifies users (for example, see Japanese Unexamined Patent Publication No. 2016-104425).

In such gaming machines, in order to increase the interest of the game, efforts have been made to diversify the gameplay with respect to, for example, the provision and transition of advantageous states (AT (assist time) states). However, by diversifying the gameplay, the gameplay may become complicated. As a result, a problem arises in that a burden is placed on the main processing that controls the game.

The present invention has been made in view of these points, and an object of the present invention is to improve the efficiency of main processing for controlling games.

internal winning combination determination means (for example, main CPU 101 that performs internal lottery processing) that determines an internal winning combination with a predetermined probability;
A variable display means (for example, reels 8A to 8D) that is composed of a plurality of display rows and displays symbols necessary for the game in a variable manner;
A stop operation detection means (for example, a stop switch 8S) that detects a stop operation by a player;
a stop control means (for example, a main CPU 101 that performs a reel stop control process) that stops the fluctuating display of the symbols based on the determination result of the internal winning combination determination means and the detection of a stop operation by the stop operation detection means; Equipped with
The internal winning combination determining means is configured to perform a specific stopping operation mode (for example, the order of the fourth reel D, third reel C, second reel B, and first reel A, and a cherry is displayed at the bottom of the fourth reel D). When the stop operation is performed at the press timing), it is possible to determine a specific combination (for example, "F_Weak Che") that can derive a specific display mode (for example, "NM19" (C_Weak Che A)). ,
When the specific display mode is derived, a specific amount (for example, 2 coins) of gaming value (for example, medals) is provided,
When a start operation for a game following the game in which the specific combination has been determined is performed, different processing (for example, , a transition process to a "stable state" (special mode ON), and a transition process to a "rough sea state" (special mode OFF)).
According to such a gaming machine, in the game following the game in which the specific combination has been determined, a judgment process is performed based on the amount of gaming value given in the game in which the specific combination has been determined, so that the specific combination is not determined. It is possible to reduce the judgment processing required in the game. As a result, the main processing for controlling the game can be made more efficient.

The gaming machine described above is characterized in that if a stop operation is not performed in the specific stop operation mode in a game in which the specific combination has been determined, a gaming value greater than the specific amount is not awarded.
According to such a gaming machine, the ease with which the game value decreases can be made different depending on whether the stop operation is performed in a specific stop operation mode or the case where the stop operation is not performed in the specific stop operation mode. .

When the start operation of the game following the game in which the specific combination has been determined is performed, if the specific amount of gaming value has been awarded in the game in which the specific combination has been determined, the first process (for example, If the specific amount of gaming value is not given in the game in which the specific combination has been determined, the second process (for example, transition to "stable state" (special mode ON)) is executed (transition processing to "stable state" (special mode ON)). (transition processing to special mode OFF)).
According to such a gaming machine, it is possible to determine whether to perform the first process or the second process based on whether or not the gaming value given in the game in which the specific combination has been determined is a specific amount. I can do it.

having a plurality of internal states including a first state (e.g., "stable state") and a second state (e.g., "rough sea state");
The first process is a process of transitioning to the first state and a process of changing the rate at which transition to an advantageous state is determined,
The gaming machine described above, wherein the second process is a transition process to the second state.
According to such a gaming machine, when a specific amount of gaming value is given in a game in which a specific combination has been determined, it is possible to change the ratio at which transition to an advantageous state is determined, and to change the rate of transition to an advantageous state. transition decisions can be varied. In addition, by selecting whether or not to perform a specific stopping operation mode, it is possible to select a destination of the internal state, thereby increasing the interest of the game.

The gaming machine described above is characterized in that if the specific stop operation mode is not performed, a predetermined display mode (for example, "NM20" (S_Weak Chee B)) can be derived.
According to such a gaming machine, by checking whether it is a specific stop operation mode or a predetermined display mode, it is possible for the player to recognize which process is to be performed subsequently. .

a display means (for example, an instruction monitor) capable of displaying information on the stop operation mode;
and a predetermined determining means (for example, a main CPU 101 that performs the Cherry Navi lottery) that makes a predetermined determination (for example, winning the Cherry Navi lottery) when the specific combination is determined,
The gaming machine described above is characterized in that the display means is capable of displaying information regarding a stop operation mode when the predetermined determination is made.
According to such a gaming machine, by displaying predetermined information, it is possible to suggest that a specific combination has been determined.

Equipped with a performance execution means (for example, main display device 210) capable of performing a performance,
The performance execution means is
When the specific role is determined, a predetermined performance (for example, a scroll performance) can be performed,
The gaming machine described above is characterized in that the mode of the predetermined effect is varied depending on whether the predetermined decision has been made.
According to such a gaming machine, it is possible to suggest that a specific combination has been determined by a predetermined performance mode.

The gaming machine described above is characterized in that the internal state can be transferred when the predetermined decision is made.
According to such a gaming machine, it is possible to make the transition of the internal state difficult, and it is possible to make the transition of the internal state rare.

The gaming machine described above, wherein the rate at which the predetermined determination is made varies depending on the internal state.
According to such a gaming machine, it is possible to make it easier to shift the internal state or to make it difficult to shift the internal state depending on the internal state.

The gaming machine described above, wherein the rate at which the predetermined decision is made in the first state is higher than the rate at which the predetermined decision is made in the second state.
According to such a gaming machine, in the first state, it is easier to suggest that a specific combination has been determined. Therefore, when performing the transition process to the first state when a specific amount of gaming value is given in a game in which a specific combination has been determined, it is possible to easily maintain the first state. Moreover, in the case of the second state, it becomes difficult to suggest that a specific combination has been determined. Therefore, when performing the transition process to the second state when a specific amount of gaming value has not been awarded, it is possible to make the transition from the second state to the first state difficult.

The gaming machine described above is characterized in that in the second state, it is easier to determine a transition to an advantageous state (for example, a pseudo bonus (AT)) than in the first state.
According to such a gaming machine, the second state can be made into a state in which there is a high possibility that the gaming value can be increased, but the player's gaming value is likely to decrease.

[Additional note 3]
In conventional gaming machines, it is possible to set a non-advantageous section and an advantageous section, set the AT state in the advantageous section, and shift from the advantageous section to the non-advantageous section when a predetermined end condition is met. This is known (for example, see Japanese Patent Application Publication No. 2017-185099).

In such advantageous sections of the game, there is an increase section (pseudo bonus) where you can expect an increase in gaming value by notifying (navigating) the order of pressing the stop operations, and an increasing section (pseudo bonus) where you can expect an increase in gaming value by not informing (navigating) the order of pressing the stop operations. It is known that the game has a repeating decreasing section in which the game value decreases. Further, one of the conditions for ending the advantageous section is, for example, a limiter of 1500G (game). In the case of the game as described above, as the number of G consumed in the advantageous section approaches 1500 G, the player becomes dissatisfied with the number of G consumed in the reduced section, which may lead to a decrease in interest in the game.

The present invention has been made in view of these points, and it is an object of the present invention to provide a gaming machine that can eliminate the dissatisfaction that players have with regard to advantageous sections.

internal winning combination determination means (for example, main CPU 101 that performs internal lottery processing) that determines an internal winning combination with a predetermined probability;
A variable display means (for example, reels 8A to 8D) that is composed of a plurality of display rows and displays symbols necessary for the game in a variable manner;
A stop operation detection means (for example, a stop switch 8S) that detects a stop operation by a player;
a stop control means (for example, a main CPU 101 that performs a reel stop control process) that stops the fluctuating display of the symbols based on the determination result of the internal winning combination determination means and the detection of a stop operation by the stop operation detection means;
Notifying means (for example, main display device 210) capable of notifying the player of a stop operation mode that is advantageous to the player;
A section control means (for example, a section control means for controlling the transition of a gaming state) between a non-advantageous section in which it is not possible to notify the stopping operation mode by the notifying means and an advantageous section in which it is possible to notify the stopping operation mode by the notifying means. a main CPU 101) that performs
In the advantageous section, there is an advantageous state (for example, "BIG bonus" of a pseudo bonus) in which the gaming value can be increased by notification of the stop operation mode, and a state that changes after the end of the advantageous state and the stop operation mode is A predetermined state in which it is not possible to increase the gaming value by notification (for example, a continuous change section),
The predetermined state is determined from a plurality of pieces of management information (e.g., tables F to I) that include at least predetermined management information (e.g., table F) and specific management information (e.g., table G) that is more advantageous than the predetermined management information. further comprising a management information determining means (for example, a main CPU 101 that performs a table type lottery) for determining one of the management information used in the
The number of games required to transition to the advantageous state when the specific management information is determined is shorter than the number of games required to transition to the advantageous state when the predetermined management information is determined. ,
The gaming machine is characterized in that the management information determining means determines the specific management information when a predetermined condition (for example, the number of remaining games in the advantageous section is less than a predetermined period) is satisfied.
According to such a gaming machine, when a predetermined condition is satisfied, the predetermined state in which it is not possible to increase the gaming value can be shortened. As a result, the period during which a predetermined state is performed can be varied depending on whether or not a predetermined condition is satisfied, thereby increasing the interest of the game.

The advantageous section ends when the number of games during the advantageous section reaches a specified number (for example, 1500),
The gaming machine described above is characterized in that the predetermined condition is that the transition to the advantageous state is determined when the number of remaining games in the advantageous section is less than a threshold value (for example, less than 500G).
According to such a gaming machine, when there are few advantageous sections remaining, it is possible to shorten the predetermined state in which it is not possible to increase the gaming value. As a result, it is possible to prevent the period in which the advantageous state can be enjoyed from being shortened, and it is possible to eliminate the dissatisfaction that the player has.

The advantageous state includes at least a first advantageous state (e.g., "BIG bonus") and a second advantageous state (e.g., "REG bonus"),
The predetermined state includes at least a first predetermined state (for example, a high probability zone) and a second predetermined state (for example, a continuous section),
The section control means is configured to control when the first predetermined state shifts to the second advantageous state, or when the second predetermined state shifts to the first advantageous state before a specific period (for example, 100G) is reached. The above-mentioned gaming machine is characterized in that if the decision is not made, the advantageous section is shifted to the non-advantageous section.
According to such a gaming machine, when a predetermined condition is satisfied, it is possible to easily determine the transition to the first advantageous state by the time a specific period is reached.

The gaming machine described above, wherein the predetermined management information and the specific management information are used in the second predetermined state.
According to such a gaming machine, when a predetermined condition is satisfied, the number of games required to shift from the second predetermined state to the first advantageous state can be shortened. As a result, even if the remaining number of games in the advantageous period is small, it is possible to secure a period in which the advantageous state can be enjoyed.

The first predetermined state is started when the non-advantageous section shifts to the advantageous section,
The gaming machine described above, wherein the second predetermined state is started after the first advantageous state ends.
According to such a gaming machine, when a predetermined condition is met, it is possible to shorten the second predetermined state that is performed between the first advantageous state in which the game value increases, thereby resolving the dissatisfaction felt by the player. be able to.

The management information determining means is characterized in that, when a transition to the first advantageous state is determined, the management information determining means determines the type of management information in the second predetermined state after the end of the first advantageous state. The above gaming machine.
According to such a gaming machine, since the type of management information is determined before the second predetermined state is started, the management information can be used from the first game in the second predetermined state.

In the predetermined state, having a plurality of advantage information (for example, map type) related to determining whether to transition to the advantageous state;
The gaming machine described above, further comprising an advantage information determining means (for example, a main CPU 101 that performs continuous zone map lottery) that determines one advantage information from a plurality of advantage information according to the management information.
According to such a gaming machine, it is possible to make various lottery transitions to advantageous states in a predetermined state.

The gaming machine described above, wherein the degree of expectation of transition to the advantageous state differs depending on the type of the advantage information.
According to such a gaming machine, it is possible to vary the degree of expectation of transition to an advantageous state in a predetermined state, and it is possible to improve the interest of the game.

The plurality of pieces of advantage information include predetermined advantage information (for example, series_normal D) and specific advantage information (for example, series_normal F) that has a higher expectation of transition to the advantageous state than the predetermined advantage information. ) and has
The gaming machine described above, wherein when the specific management information is determined, the specific advantage information is determined more easily than when the predetermined management information is determined.
According to such a gaming machine, specific advantage information can be determined more easily when predetermined conditions are met, and the degree of expectation of transition to an advantageous state is higher than when the predetermined conditions are not met. be able to.

The gaming machine described above is characterized in that the probability that advantageous information with a high expectation of transition to an advantageous state is determined varies depending on a set value.
According to such a gaming machine, it is possible to vary the degree of expectation of transition to an advantageous state depending on the set value, and it is possible to improve the interest of the game.

[11. Third gaming machine]
Next, with reference to FIGS. 124 to 145, another specific example of the control system of a pachi-slot machine will be described as a "third gaming machine." It should be noted that part or all of the configuration of the control system described as the third gaming machine in this embodiment can be applied to other gaming machines described in this embodiment. Part or all of the configuration of the control system described as another gaming machine in this embodiment can be applied to the third gaming machine described in this embodiment. That is, the invention according to this embodiment can be a combination of these as appropriate.

[11-1. Pachislot machine control system configuration]
First, with reference to FIG. 124, the configuration of the control system included in the third gaming machine (pachislot machine) will be described. FIG. 124 is a block diagram showing the configuration of the control system of the third gaming machine (pachislot machine). Note that the components in the control system of the third gaming machine shown in FIG. 124 are the same as the components in the control system of the first and second gaming machines explained in FIG. 3 and FIG. are given the same reference numerals, and explanations of their constituent parts will be omitted.

As shown in FIG. 124, the third gaming machine (pachislot machine) has a main control section 600, a sub-control section 620, and a control signal line (solid line arrow in FIG. 124) connected to the main control section 600. and a plurality of peripheral devices.

The main control unit 600 is a component that controls the progress of the game, and includes a main control board 601, a drum unit board 602 (relay board), and a door relay board 603 (relay board). Note that the internal configuration of each of these substrates will be described in detail later.

The main control board 601, drum unit board 602, and door relay board 603 are connected by an optical fiber cable (double arrow in FIG. 124). Specifically, an optical communication output connector A provided on the main control board 601 is connected to an optical communication input connector D provided on the reel device board 602 via an optical fiber cable, and the reel device board 602 The optical communication output connector E provided on the door relay board 603 is connected to the optical communication input connector F provided on the door relay board 603 via an optical fiber cable, and the optical communication output connector G provided on the door relay board 603 is connected to the optical communication output connector F provided on the door relay board 603. , is connected to an optical communication input connector B provided on the main control board 601 via an optical fiber cable.

The communication between the main control board 601, the drum device board 602, and the door relay board 603 is one-way communication, and the data sent from the main control board 601 is transmitted to the drum device board 602 and the door relay board 603. The information is transmitted sequentially and finally transmitted from the door relay board 603 to the main control board 601. That is, the data transmitted from the main control board 601 circulates through the drum device board 602 and the door relay board 603 in this order, and returns to the main control board 601. Furthermore, data communication between each board is synchronous serial communication, and the interval is less than or equal to the period of periodic interrupt processing (1 interrupt time: 1.1172 ms) performed by the main CPU (see Figure 131 described later). It will be carried out in

In addition, in the third game machine, an example will be described in which the main control board 601, the drum unit board 602, and the door relay board 603 are connected by an optical fiber cable, but the present invention is not limited to this, and for example, the connection is possible. These three boards may be connected using a communication cable (harness). Furthermore, in the third gaming machine, as described above, an example will be described in which the transmission data circulates from the main control board 601 to the drum unit board 602 and the door relay board 603 in this order, and returns to the main control board 601. However, the present invention is not limited to this, and the transmission data may be configured such that it circulates from the main control board 601 to the door relay board 603 and the drum unit board 602 in this order, and returns to the main control board 601. Good too. In this case, in the block diagram shown in FIG. 124, the direction of the double line arrow connecting the main control board 601, the drum device board 602, and the door relay board 603 (the direction of communication via the optical fiber cable) is reversed. The manner in which the optical fiber cable is connected to each board is changed as appropriate.

The sub-control unit 620 is a component that controls various presentation devices (for example, display devices, speakers, lamps, accessories, etc.) (not shown) in response to commands from the main control unit 600, and controls the sub-relay board 621 and the sub-relay board 621. It has a control board 622 and a VDP board 623. Note that the internal configuration of the sub-control unit 620 will be described in detail later.

In the third gaming machine, an optical communication output connector C provided on the main control board 601 is connected to an optical communication input connector C provided on the sub relay board 621 via an optical fiber cable (double line arrow in FIG. 124). The communication between the main control unit 600 and the sub-control unit 620 connected to the connector H is one-way communication from the main control unit 600 to the sub-control unit 620. Furthermore, data communication between the main control unit 600 and the sub-control unit 620 is asynchronous serial communication. In addition, in the third game machine, an example will be described in which the main control section 600 and the sub-control section 620 are connected using an optical fiber cable, but the present invention is not limited to this, and for example, a connectable communication cable may be used. , the main control section 600 and the sub-control section 620 may be connected.

The plurality of peripheral devices include the hopper device 32 (including the medal auxiliary storage 33), the key-type setting switch 52, and the external centralized terminal board 55, which are connected to the main control unit 600. In addition, the plurality of peripheral devices include a left reel 3L (first reel), a middle reel 3C (second reel), and a right reel 3R (third reel), which are connected to the reel device board 602. It will be done. Furthermore, the plurality of peripheral devices include an information display device 14 (LED status display device), a medal sensor 31S (medal selector), a stop switch 8S (stop switch board), and a payment switch 9S ( A checkout button 9), a start switch 7S (start lever 7), an error release switch 57 (reset switch 53), and a door opening/closing monitoring switch 56 are included.

In the third gaming machine, as shown in FIG. 124, a main control board 601, a drum unit board 602, a door relay board 603, and a sub relay board 621 each have a first HB-LSI (Hybrid-Large Scale Integration). 611, a second HB-LSI 612, a third HB-LSI 613, and a fourth HB-LSI 614 are mounted. Each HB-LSI is an LSI (ASIC: Application Specific Integrated Circuit) that has multiple types of functions such as a communication function, a data port input/output function, a random number generation function, and an LED driving function.

In the third gaming machine, HB-LSIs having the same configuration (specifications) are used as the first HB-LSI 611, the second HB-LSI 612, the third HB-LSI 613, and the fourth HB-LSI 614. Note that the present invention is not limited to this, and for example, HB-LSIs with different configurations (specifications) may be used for each board depending on the type of board to be mounted.

In the third gaming machine, the first HB-LSI 611 provided on the main control board 601 is set as a master, and the second HB- The LSI 612 and the third HB-LSI 613 are set as slaves. Furthermore, in the third gaming machine, communication between the main control section 600 and the sub-control section 620 is one-way communication from the main control section 600 to the sub-control section 620, The fourth HB-LSI 614 is also set as a slave. Note that the internal configuration of the HB-LSI used in the third gaming machine will be described in detail later.

In addition, in the third gaming machine, the main control unit 600 (main control board 601) is used for the certification test (sight shooting test) of the pachi-slot machine by the control signal line for the test shooting test (broken line arrow in FIG. 124). It is connected to a first interface board 301 (relay board) for the test machine. Further, the main control unit 600 (main control board 601) is configured to control a second interface board 302 for a test machine or a third interface board for a test machine, separately from the first interface board 301 for a test machine, depending on the test content. Connected to board 303. The second interface board 302 for the testing machine is a relay board for the maximum ball output test, and the third interface board 303 for the test machine is a relay board for the minimum ball output test. It is never connected to. Note that in any test content, the first interface board 301 for the testing machine is connected to the main control unit 600.

The control system of the third gaming machine can also be applied to a medalless gaming machine, and when the third gaming machine is a medalless gaming machine, the medal number control board 650 is provided as a relay board, and the medal number control board 650 is provided as a relay board. The control board 650 is connected to the main control board 601 of the main control unit 600 by a control signal line (dotted chain arrow in FIG. 124). The configuration of the medal number control board 650 and the connection mode with the main control unit 600 (dotted chain arrow in FIG. 124) are similar to the medal number control board (gaming value management device) described in the first gaming machine (see FIG. 34). ) are similar to those of

Further, if the third gaming machine is a medalless gaming machine, the medal selector and hopper device 32 (including the medal auxiliary storage 33) are not provided, or even if provided, the main control unit 600 Not connected. Furthermore, if the third gaming machine is a medalless gaming machine, although not shown in FIG. 124, the medal number control board 650 is connected to a gaming value providing device called "Sand". In this case, a microprocessor (not shown) for controlling the number of medals for controlling the gaming value providing device may be provided in the medal number control board 650 or in the main control board 601. In the latter case, the main control board 601 becomes a main control board dedicated to a medalless gaming machine on which both a microprocessor 610 for game control and a microprocessor for controlling the number of medals are mounted.

[11-2. Configuration of information display device]
Next, a specific configuration example of the information display device 14 used in the third gaming machine will be described with reference to FIGS. 125 and 126. FIG. 125 is a diagram showing an example of the configuration of the information display device 14 used when the gaming machine is a normal (non-medalless) gaming machine. FIG. 126 is a diagram showing an example of the configuration of the information display device 14 used when the gaming machine is a medalless gaming machine.

(Information display device used in normal gaming machines)
As shown in FIG. 125A, the information display device 14 used in a normal gaming machine includes various lamps (status display lamps) that indicate the operating status of the game, such as an "INSERT" lamp, a "START" lamp, and a "REPLAY" lamp. , and bet number display lamps labeled "1BET,""2BET," and "3BET." Each status display lamp is composed of one LED (Light Emitting Diode).

The "INSERT" lamp is a lamp that lights up when it is possible to insert medals, the "START" lamp is a lamp that lights up when it is possible to start a game, and the "REPLAY" lamp is a lamp that lights up when it is possible to insert medals. This lamp lights up when it is possible to play again due to a winning replay combination. In addition, the "1BET", "2BET" and "3BET" lamps are displayed depending on the number of bets on the gaming value (game media or storage) (the number of bets made by inserting the gaming value or pressing the MAX bet button 6a and 1 bet button 6b). This is a lamp that lights up.

Further, the information display device 14 used in a normal gaming machine is provided with a 7-digit 7-segment LED (hereinafter referred to as "7-segment LED"). Note that each 7-segment LED is composed of seven segments a to g arranged in the manner shown in FIG. 125B.

Among the 7-digit 7-segment LEDs, the lamp consisting of the 2-digit 7-segment LED on the left side of the diagram (above the "CREDIT" notation) indicates the number of stored gaming values (credits) deposited inside the pachislot machine. This is a credit display lamp for digitally displaying (notifying) information such as the number of players.

Among the 7-digit 7-segment LEDs, the lamp consisting of the 2-digit 7-segment LED on the right side of the diagram (above the "PAY" notation) displays information on the number of payouts (number of grants) of gaming value to the player. This is a payout indicator lamp for digital display (notification). Note that the two-digit 7-segment LED constituting the payout indicator lamp is also used as an error indicator lamp for digitally displaying (notifying) information on the occurrence of an error and the type of error to the player.

In addition, among the 7-digit 7-segment LEDs, the lamp composed of the central 3-digit 7-segment LED is used to stop the lamp that is necessary to display the symbol combination according to the determined internal winning combination along the active line. This is an instruction monitor for notifying operation information. This instruction monitor notifies the player of the necessary stop operation information by lighting, blinking, or extinguishing a 3-digit 7-segment LED in a manner that uniquely corresponds to the information on the stop operation to be notified. .

Note that the display mode of the stop operation information on the instruction monitor (3-digit 7-segment LED) is arbitrary, but for example, among the 3-digit 7-segment LEDs, the leftmost (3rd digit) The information displayed on the 7-segment LED located at is information regarding the stop operation of the left reel 3L, the information displayed on the 7-segment LED located at the center (second digit) is information regarding the stop operation of the middle reel 3C, The information displayed on the 7-segment LED located on the rightmost side (first digit) may be used as information regarding the stop operation of the right reel 3R.

Specifically, when the reels are stopped in the order of middle reel 3C, right reel 3R, and left reel 3L, the 7-segment LED located at the center (second digit) of the instruction monitor (three-digit 7-segment LED) "1" is displayed as information regarding the stop operation (suggestion of pressing the stop button 8C) of the middle reel 3C, which is the first stop target, and the 7-segment LED located on the right side (first digit) indicates that the middle reel 3C is the second stop target. "2" is displayed as information regarding the stop operation of the right reel 3R (suggestion of pressing the stop button 8R), and the 7-segment LED located on the left side (3rd digit) indicates the stop operation of the left reel 3L, which is the third stop target. "3" is displayed as information regarding (suggestion of pressing the stop button 8L).

Also, for example, information regarding the stop operation of the left reel 3L, middle reel 3C, and right reel 3R can be displayed using only the 7-segment LED located in the center (second digit) of the instruction monitor (three-digit 7-segment LED). May be displayed. Specifically, when the 7-segment LED located at the center (second digit) displays, for example, "1", that information is used as information regarding the stop operation for the left reel 3L (suggestion of pressing the stop button 8L). If "2" is displayed, the information is used as information regarding the stop operation for the middle reel 3C (suggestion of pressing the stop button 8C), and when "3" is displayed, the information is used as the information for the right reel 3R. This is information regarding the stop operation (suggestion of pressing the stop button 8R).

(Information display device used in medalless gaming machines)
As shown in FIG. 126, the information display device 14 used in the medalless gaming machine includes a status display monitor 14a and an instruction monitor 14b. In addition, in the third gaming machine, the status display monitor 14a and the instruction monitor 14b are arranged as separate bodies on the pedestal part of the gaming machine.

The status display monitor 14a is provided with a ``START'' lamp, a ``REPLAY'' lamp, a ``1BET'' lamp, a ``2BET'' lamp, and a ``3BET'' lamp as status display lamps that indicate the operating status of the game. Note that each lamp is composed of one LED (segment). Further, the status display monitor 14a is provided with a 5-digit, 7-segment LED for digitally displaying (notifying) information such as the number of stored gaming values (number of credits) to the player. Note that the number of payouts (number of awards) of game value is added to the number of credits, and the addition result is displayed on a five-digit 7-segment LED.

The instruction monitor 14b is composed of a 3-digit 7-segment LED, and notifies information on a stop operation necessary for displaying a symbol combination according to a determined internal winning combination along an active line. The configuration of the instruction monitor 14b is similar to the configuration of the instruction monitor used in the above-mentioned normal gaming machine, and the configuration of the 7-segment LED of each digit making up the instruction monitor 14b is also the same as that of the normal gaming machine ( (see FIG. 125A).

[11-3. HB-LSI configuration]
Next, a configuration example of the HB-LSI (first HB-LSI 611 to fourth HB-LSI 614) used in the third gaming machine will be explained. As mentioned above, the first HB-LSI 611 to the fourth HB-LSI 614 used in the third gaming machine are LSIs with the same configuration, so for convenience of explanation, these HB-LSIs will be referred to as HB-LSIs. It is written as LSI700.

FIG. 127 is a block diagram showing the internal configuration of the HB-LSI 700. As shown in FIG. 127, the HB-LSI 700 (input/output communication means) includes a serial bus communication circuit 701 (first communication section), an asynchronous serial communication circuit 702 (second communication section), and an LED drive circuit 703 (display a 7-seg character data storage unit 704, a PIO (Parallel Input/Output) circuit 705 (signal input/output unit), a controller 706, an external bus interface 707 (hereinafter referred to as an “external bus I/F '') and a random number generation circuit 708 (random number generation section). Each of these parts constituting the HB-LSI 700 is connected to each other via an internal bus 709.

(Serial bus communication circuit)
The serial bus communication circuit 701 is a circuit that controls data communication (sending and receiving) operations when performing synchronous serial bus communication between the board on which the serial bus communication circuit 701 is mounted and an external board. The third gaming machine uses a clock-synchronous two-wire (I2C compliant) serial communication method as the synchronous communication method, but a clock-synchronous three-wire (SPI compliant) serial communication method is used. May be adopted.

The serial bus communication circuit 701 is connected to the “OP_I” terminal (input terminal) and the “OP_O” terminal (output terminal) of the HB-LSI 700. The "OP_I" terminal (input terminal) can be connected to the optical communication input connector used in synchronous serial communication on the board on which the HB-LSI700 is mounted, and the "OP_O" terminal (output terminal) on the board It can be connected to an optical communication output connector used in synchronous serial communication (see FIGS. 131 to 133 described later). For example, when the HB-LSI 700 is the first HB-LSI 611 (master) mounted on the main control board 601, the "OP_I" terminal of the serial bus communication circuit 701 of the first HB-LSI 611 is connected to the main control board 601. It is connected to the communication input connector B, and the "OP_O" terminal is connected to the optical communication output connector A of the main control board 601 (see FIG. 131 described later).

(Asynchronous serial communication circuit)
The asynchronous serial communication circuit 702 (UART: Universal Asynchronous Receiver Transmitter) performs data communication (sending and receiving) operations when performing asynchronous serial communication between the board on which the asynchronous serial communication circuit 702 is mounted and an external board. This is a circuit that controls the Specifically, the asynchronous serial communication circuit 702 mainly performs processing for converting a serial signal into a parallel signal and signal conversion processing in the opposite direction using an asynchronous method. Furthermore, in the third gaming machine, the asynchronous serial communication circuit 702 is capable of not only transmitting and receiving fixed length data but also transmitting and receiving variable length data. Note that the internal configuration and various functions of the asynchronous serial communication circuit 702 will be described in detail later.

The asynchronous serial communication circuit 702 is connected to the "O_RX" terminal (reception terminal) and "O_TX" terminal (transmission terminal) of the HB-LSI 700. The "O_RX" terminal (reception terminal) can be connected to the optical communication input connector used in asynchronous serial communication on the board on which the HB-LSI700 is mounted, and the "O_TX" terminal (transmission terminal) can be connected to the It can be connected to an optical communication output connector used in asynchronous serial communication (see FIGS. 131 and 134 described later).

Note that in the third gaming machine, as described above, asynchronous serial communication is performed between the main control unit 600 (main control board 601) and the sub-control unit 620 (sub-relay board 621). The circuit 702 is used in the first HB-LSI 611 (master) mounted on the main control board 601 and the fourth HB-LSI 614 (slave) mounted on the sub-relay board 621. Therefore, the asynchronous serial communication circuit 702 of the first HB-LSI 611 (master) is connected to the optical communication output connector C (see FIG. 131 described later) of the main control board 601 via the "O_TX" terminal of the first HB-LSI 611. be done. Further, the asynchronous serial communication circuit 702 of the fourth HB-LSI 614 (slave) is connected to the optical communication input connector H of the sub-relay board 621 via the "O_RX" terminal of the fourth HB-LSI 614 (see FIG. 134 described later). reference).

(LED drive circuit, 7-segment character data storage)
The LED drive circuit 703 is an LED driver circuit for controlling an externally provided LED device (including a 7-segment LED and a lamp composed of one LED). In addition, in the third gaming machine, the LED drive circuit 703 of the third HB-LSI 613 mounted on the door relay board 603 is connected to the 7-segment LED and status display provided on the information display device 14 connected to the door relay board 603. Used to control lamp display operations.

The LED drive circuit 703 is connected to the "POa" to "POg" terminals and the "AS0" to "AS15" terminals of the HB-LSI 700, and these terminals are connected to the external LED device to be controlled (the third gaming machine). Then, it is connected to the information display device 14). Specifically, the "POa" to "POg" terminals are the cathodes of segments a to segment g (see FIG. 125B) that constitute each of the 7-segment LEDs included in the LED device (information display device 14), and the respective states. It is connected to the cathode of the indicator lamp (see FIGS. 125A and 126), and the "AS0" to "AS15" terminals are connected to the anode of each LED (cathode common connection method). The "POa" to "POg" terminals are set with data (character data) corresponding to the form of information (numbers and characters) actually displayed on the 7-segment LED, and on/off data for each status display lamp. A control signal for anode selection when controlling an external 7-segment LED device to be controlled using a dynamic control method is set in the "AS0" to "AS15" terminals. Note that the connection mode between the LED drive circuit 703 of the third HB-LSI 613 and the information display device 14 via the "POa" to "POg" terminals and the "AS0" to "AS15" terminals is such that the gaming machine is a medalless gaming machine. The connection mode will be described in detail later.

The 7-segment character data storage unit 704 stores display data acquired by the HB-LSI 700 via the serial bus communication circuit 701 in the form of information (numbers and characters) actually displayed on the 7-segment LED, that is, for each 7-segment character data storage unit 704. Data for converting into character data corresponding to lighting/extinguishing states of segments a to g constituting the segment LED is stored. Specifically, display data acquired via the serial bus communication circuit 701 (for example, "7-segment display data" in FIG. 144 described later) and character data corresponding to the actual display mode on the 7-segment LED The correspondence relationship with 7-segment character data storage unit 704 is stored in the 7-segment character data storage unit 704.

In the third gaming machine, the HB-LSI 700 converts the 2-byte display data acquired via the serial bus communication circuit 701 into character data for 2-digit 7-segment LED display. Therefore, the 7-segment character data storage unit 704 contains a data table (not shown; , referred to as "corresponding data table") are stored.

For example, 2-byte display data "0AH" acquired via the serial bus communication circuit 701 and character data for displaying the number "10" on a 2-digit 7-segment LED are associated in a corresponding data table. Assume that it is stored in . In this case, if the HB-LSI 700 (serial bus communication circuit 701) receives "0AH" as the 2-byte display data for 7-segment LED display, the HB-LSI 700 receives the 2-byte display data based on the corresponding data table. Display data is converted into character data for displaying the number "10" on a two-digit 7-segment LED.

Also, for example, 2-byte display data "75H" acquired via the serial bus communication circuit 701 is associated with character data for displaying the character "EE" on a 2-digit 7-segment LED. Assume that it is stored in a data table. In this case, if the HB-LSI 700 (serial bus communication circuit 701) receives "75H" as 2-byte display data for 7-segment LED display, the HB-LSI 700 uses this 2-byte display data based on the corresponding data table. The display data is converted into character data for displaying the character "EE" on a two-digit 7-segment LED.

Also, for example, the 2-byte display data "01H" acquired via the serial bus communication circuit 701 and the 2-digit 7-segment LED indicate "1" (the first digit is "1" and the second digit is "blank"). ) is stored in the correspondence data table in association with character data for displaying the characters. In this case, if the HB-LSI 700 (serial bus communication circuit 701) receives "01H" as the 2-byte display data for 7-segment LED display, the HB-LSI 700 receives the 2-byte display data based on the corresponding data table. Display data is converted into character data for displaying the character "1" on a 2-digit 7-segment LED.

Although not shown in FIG. 127, the HB-LSI 700 also contains 2-byte display data ("7 segment display data" and "status display data" in FIG. 144, which will be described later) acquired via the serial bus communication circuit 701. ) are provided. Specifically, five 2-byte length first segment registers 0 to 4 and three 2-byte length second segment registers 0 to 2 are provided in the HB-LSI 700. Each segment register can store up to two digits of 7 segment LED display data.

The first segment registers 0 to 4 are segment registers that mainly store 2-byte display data for normal gaming machines, and the second segment registers 0-2 store 2-byte display data for medalless gaming machines. This is the segment register that is used. That is, in the third gaming machine, the HB-LSI 700 is compatible with not only the information display device 14 for normal gaming machines (see FIG. 125) but also the information display device 14 for medalless gaming machines (see FIG. 126). This is a possible configuration. As will be described later, the first segment registers 2 and 3 are set with display data for controlling lighting/extinguishing of the instruction monitor included in the information display device 14, and the first segment register 4 is set with display data for controlling lighting/extinguishing of the instruction monitor included in the information display device 14. Since the display data for controlling the lighting/extinguishing of each status display lamp (LED) included in 14 is set, the first segment registers 2 to 4 are used in both the normal gaming machine and the medalless gaming machine. .

Here, the flow from the conversion operation into 7-segment LED character data to the setting operation of 7-segment LED character data, which is executed in the third gaming machine, will be briefly described. In the third gaming machine, first, the display data (2 bytes) for the 7-segment LED acquired via the serial bus communication circuit 701 of the HB-LSI 700 (third HB-LSI 613) is stored in the first segment register or the second segment register. Set. At this time, if the gaming machine is a normal gaming machine, the display data (2 bytes) for the 7-segment LED acquired via the serial bus communication circuit 701 is set to any of the first segment registers 0 to 3. be done. On the other hand, if the gaming machine is a medalless gaming machine, the display data (2 bytes) for the 7-segment LED acquired via the serial bus communication circuit 701 is stored in the first segment registers 2 to 3 and the second segment registers 0 to 2. set to one of the following.

Next, under the control of the controller 706, the display data set in the first segment register or the second segment register is actually displayed on the 7-segment LED based on the correspondence table data stored in the 7-segment character data storage section 704. is converted into character data corresponding to the information (numbers and letters). The converted character data is then set to the "POa" to "POg" terminals of the HB-LSI 700 (third HB-LSI 613) via the LED drive circuit 703. At this time, a control signal for anode selection corresponding to the current dynamic control state of the 7-segment LED is set in the "AS0" to "AS15" terminals of the HB-LSI 700.

(PIO circuit)
The PIO circuit 705 includes "PI0" to "PI15" terminals (input terminals), "PO0" to "PO15" terminals (output terminals), and "S0" to "S2" terminals (input terminals for address setting) of the HB-LSI 700. ), and is a port input/output circuit that inputs and outputs signals (information) through these terminals.

The "PI0" to "PI15" terminals are terminals used when signals are input to the PIO circuit 705 from peripheral devices (input peripheral devices) such as external devices, switches, and boards. '' terminal is a terminal used when outputting a signal from the PIO circuit 705 to a peripheral device (output peripheral device) such as an external device or a board.

Further, the "S0" to "S2" terminals are connected to a 5V power supply or GND (ground). The "S0" terminal is a terminal (main/sub switching terminal) for setting whether the HB-LSI 700 is an LSI for the main control unit 600 (main side) or an LSI for the sub control unit 620 (sub side). When one of the 5V power supply and GND is connected to the "S0" terminal of the main side HB-LSI700 (main setting), the 5V power supply and GND are connected to the "S0" terminal of the sub-side HB-LSI700. The other is connected (sub-configured). The "S1" and "S2" terminals are address setting terminals of the HB-LSI700, and the 5V power supply or GND set to "S1" and the 5V power supply or GND set to the "S2" terminal are connected. Address setting is performed by the combination.

In the HB-LSI 700 set as a slave, when outputting data received by the serial bus communication circuit 701 from the HB-LSI 700 set as a master to a peripheral device, the PIO circuit 705 outputs the data received by the serial bus communication circuit 701. is set to the "PO0" to "PO15" terminals as port output data and output. In addition, in the HB-LSI 700 set as a slave, when transmitting data input from a peripheral device via the "PI0" to "PI15" terminals to the HB-LSI 700 set as a master, the PIO circuit 705 Data input via the terminals PI0 to PI15 (port input data) is set as transmission data of the serial bus communication circuit 701.

In addition, in the third gaming machine, the connection between the main CPU of the microprocessor 610 and the HB-LSI 700 (first HB-LSI 611), which is set as a master, is through an external bus I/F 707 built in the HB-LSI 700, and a bus described later. 606 (including data bus, address bus, etc.) and the main CPU via a built-in external bus I/F. Therefore, the main CPU can perform port input/output of data to the "PI0" to "PI15" terminals and "PO0" to "PO15" terminals in the HB-LSI 700. That is, the main CPU can use the HB-LSI 700 as a PIO circuit.

(controller)
The controller 706 is a control device for controlling the operation (function) of each circuit included in the HB-LSI 700.

(External bus I/F)
The external bus I/F 707 is a circuit that includes a data bus, an address bus, etc., and performs data input/output control with a host side device (main CPU, sub CPU) via the bus. The external bus I/F 707 is connected to "D0" to "D7" terminals and "A0" to "A15" terminals provided on the HB-LSI 700. The "D0" to "D7" terminals are terminals used when inputting and outputting data with external devices etc. via the external bus I/F707, and the "A0" to "A15" terminals are used for inputting and outputting data with external devices etc. This is a terminal used when inputting/outputting address data to/from a device etc. via the external bus I/F 707.

Here, an example has been described in which the number of terminals (data bus terminals) used for data input/output in the external bus I/F 707 is eight (input/output terminals for 8 bits). However, the number of terminals used for data input/output (data bus terminals) may be 16 (input/output terminals for 16 bits), for example. Also, here we have explained an example in which the number of terminals (address bus terminals) used for inputting and outputting address data in the external bus I/F 707 is 16 (input/output terminals for 16 bits). The invention is not limited thereto; for example, the number of terminals (data bus terminals) used for address input/output may be 32 (input/output terminals for 32 bits).

(Random number generation circuit)
The random number generation circuit 708 is a circuit for generating a 16-bit random value. In the third gaming machine, the HB-LSI 700 in which the random number generation circuit 708 is used is the first HB-LSI 611 mounted on the main control board 601, and the random number generation circuit 708 of the first HB-LSI 611 uses the internal winning combination Generate random numbers used in the lottery. Note that the internal configuration and operation contents of the random number generation circuit 708 will be described in detail later.

(Summary of HB-LSI features)
Each board on the main side of a conventional gaming machine includes an ASIC (master) that includes a random number generation circuit, a PIO circuit, and a serial bus communication circuit between master and slave, a PIO circuit, a serial bus communication circuit between master and slave, An ASIC (slave) including an LED driving circuit, and an ASIC (security LSI) including an asynchronous serial communication circuit (encrypted communication circuit) between the main and sub are provided separately. On the other hand, each board on the main side of the third gaming machine has the random number generation circuit 708, the PIO circuit 705, the master-slave serial bus communication circuit 701, the LED drive circuit 703, and the main board as described above. - An asynchronous serial communication circuit 702 between subs (capable of handling variable length data) is mounted in one HB-LSI 700.

That is, in each board on the main side of the third gaming machine, the configuration of the HB-LSI 700 is a configuration in which three types of conventional ASICs are combined into one. In addition, in the third gaming machine, the master and slave settings of the HB-LSI 700 are switched by the combination of signals (voltages) input to the "S0" to "S2" terminals of the PIO circuit 705 (voltage application mode). It will be done.

[11-3-1. Internal configuration of asynchronous serial communication circuit]
In the third gaming machine, as described above, the asynchronous serial communication circuit 702 built into the HB-LSI 700 is a communication circuit used for communication between the main and sub (communication speed: 230,400 bps to 460,800 bps). Therefore, the asynchronous serial communication circuit 702 is used in the first HB-LSI 611 (master) mounted on the main control board 601 and the fourth HB-LSI 614 (slave) mounted on the sub-relay board 621.

Note that the data (command data) transmitted from the main control unit 600 to the sub-control unit 620 by asynchronous serial communication includes various data related to the game status (“d1” to “dn” in FIG. 137 described later; hereinafter, (hereinafter referred to as "game control data"), data indicating the start of the transmission data ("STX (Start of Text)" in FIG. 137 described later: hereinafter referred to as "start data"), and data indicating the end of the transmission data. data (“ETX (End of Text)” in FIG. 137 described later: hereinafter referred to as “end data”) and error detection code data (described later) for detecting abnormalities that occur with the transfer of game control data. CRC (Cyclic Redundancy Check) 16 in FIG. 137).

Further, the third gaming machine is provided with a function (data conversion function) to perform DLE (Data Link Escape) control on game control data in generating transmission data (command data). If the game control data is the same as the start data (7EH) or end data (7FH), DLE control (conversion) is applied to the game control data, and the game control data before conversion is determined to have been DLE controlled. (7DH: hereinafter referred to as "DLE data") and the converted game control data. Further, in the third gaming machine, even when the gaming control data is DLE data (7DH), DLE control (conversion) is performed on the gaming control data. Note that the structure of the command data and the contents of the DLE control will be described in detail later.

FIG. 128 is a block diagram showing the internal configuration of asynchronous serial communication circuit 702. As shown in FIG. 128, the asynchronous serial communication circuit 702 includes a first data set register 711 (first register), a second data set register 712 (second register), a data read register 713, and a status monitoring circuit 714. , baud rate generation circuit 715, option grant/check circuit 716, CRC16 generation/check circuit 717, transmission data buffer 718 (data buffer), transmission shift register 719, reception shift register 720, reception data buffer 721 and has.

(1st data set register, 2nd data set register, data read register)
The first data set register 711 is a register that stores (sets) game control data to be transmitted to the outside, and outputs and writes the stored game control data to the transmission data buffer 718. The first data set register 711 stores gaming control data that is transmitted first (hereinafter referred to as "first gaming control data") among a plurality of gaming control data included in one packet of gaming control data group to be transmitted. Each game control data is sequentially stored from the game control data transmitted to the last game control data (hereinafter referred to as "last game control data") to the game control data transmitted immediately before. Note that the process of setting game control data to the first data set register 711 is controlled by the host (main CPU in the third gaming machine).

Similarly to the first data set register 711, the second data set register 712 is also a register that stores game control data to be transmitted to the outside, and outputs and writes the stored data to the transmission data buffer 718. The second data set register 712 stores the last gaming control data included in the gaming control data group of one packet to be transmitted. Note that the process of setting the game control data to the second data set register 712 is controlled by the host (main CPU in the third gaming machine).

Furthermore, in the third gaming machine, when the last gaming control data is stored in the second data set register 712, it is determined that writing of one packet of gaming control data group is completed. Therefore, by storing the gaming control data by the second data set register 712 and writing it to the transmission data buffer 718, the data length of the command data to be transmitted (gaming control data + start data + end data + error detection code data) can be changed. Determine. In addition, in the third gaming machine, the data length of one packet of gaming control data group transmitted and received by the asynchronous serial communication circuit 702 can be made variable, and the maximum data length is 32 bytes.

Note that in the third gaming machine, transmission packet data counters (not shown) that store (count) the data size of one packet written to the transmission data buffer 718 are provided for the number of packets written to the transmission data buffer 718. It will be done. Then, at the time when the second data set register 712 writes the last game control data to the transmission data buffer 718, the transmission packet data counter indicates that the game control data is written to the transmission data buffer 718 by the first data set register 711. The number of times game control data has been written to the transmission data buffer 718 by the second data set register 712 (one time) is set to the number of times (number of bytes). Also, at this time, a transmission packet data counter used for transmission data of one packet to be transmitted next is initialized (set to "0"). For example, if 5 packets of game control data are written in the transmission data buffer 718, and the data size of 1 packet is set to the 5th transmission packet data counter, the 6th transmission packet data counter will be Initialized.

The value of the transmission packet data counter is decremented (updated) by 1 each time 1 byte of game control data in the corresponding 1 packet of transmission data is transmitted. Note that if the gaming control data written in the transmission data buffer 718 is data subject to DLE control, the value of the transmission packet data counter is not subtracted when transmitting the DLE data, and the gaming control after DLE control (conversion) At the time of data transmission, the value of the transmission packet data counter is decremented by 1.

In the third gaming machine, an example will be explained in which the minimum size of the game control data group is 2 bytes, and for example, when writing a 5-byte game control data group to the transmission data buffer 718, the 1st to 4th bytes A configuration example in which the game control data of the 5th byte is set in the first data set register 711 and written to the transmission data buffer 718, and the game control data of the 5th byte is set in the second data set register 712 and written to the transmission data buffer 718. However, the present invention is not limited thereto. For example, the minimum size of the game control data group may be set to 1 byte. In this case, when writing the 1-byte game control data group to the transmission data buffer 718, the first data set register 711 is not used, and the 2. Game control data is set in the data set register 712 and written in the transmission data buffer 718.

The data read register 713 is a register that reads game control data received from the outside from the reception data buffer 721 and stores (sets) it. Note that the received data set in the data read register 713 is read by the host (sub CPU 615 in the third gaming machine).

(Status monitoring circuit)
The status monitoring circuit 714 is a circuit that monitors the communication status in the asynchronous serial communication circuit 702. Specifically, the status monitoring circuit 714 monitors the states of the transmission data buffer 718, reception data buffer 721, and the like. For example, when all received data is read from the received data buffer 721, the status monitoring circuit 714 monitors the presence/absence of received data and the result becomes null.

The status monitoring circuit 714 includes a 1-byte long status register T that stores various information regarding the transmission status (transmission operation), and a 1-byte long status register R that stores various information regarding the reception status (reception operation). is provided. The status register T stores various information regarding the state of the transmission data buffer 718 on a bit-by-bit basis, and the status register R stores various information on the state of the receiving data buffer 721 on a bit-by-bit basis.

129A and 129B are diagrams showing the configurations of status register T and status register R, respectively. As shown in FIG. 129A, in the status register T, as information regarding the transmission status, information called "buffer ready" is set to bit 0, information called "buffer empty 1" is set to bit 1, and information called "buffer empty" is set to bit 1. Information called "Empty 2" is set in bit 2, information called "Buffer Full" is set in bit 3, information called "Transfer Error" is set in bit 4, and information called "Access Protect" is set in bit 4. 5, and information called "active" is set in bit 6. Note that bit 7 of status register T is unused.

Note that in the third gaming machine, confirmation (reading) and setting (writing) of various information regarding the transmission status stored in the status register T can be executed by the main CPU serving as a host for the transmission operation. However, the main CPU can only check (read) bits 0 to 4 in status register T (see "R/-" notation in FIG. 129A), but bits 5 to 6 It is possible to perform both confirmation (reading) and setting (writing) for (see "R/W" notation in FIG. 129A).

“Buffer Ready” (bit 0) in the status register T stores information on the acceptance state of data transfer (writing) to the transmission data buffer 718. If it cannot be accepted, "0" (off) is set to "buffer ready" (bit 0), and if it is acceptable, "1" (on) is set to "buffer ready" (bit 0). be done.

“Buffer empty 1” (bit 1) in the status register T stores information about the state of the transmission data buffer 718 (whether it is empty or not). If there is one packet (or one byte) or more of data in the transmission data buffer 718, “0” (off) is set to “buffer empty 1” (bit 1), and one packet (or one byte) is stored in the transmission data buffer 718. If there is no data (1 byte), "1" (on) is set to "buffer empty 1" (bit 1).

“Buffer Empty 2” (bit 2) in the status register T stores information on the state of the transmission data buffer 718 (whether or not the empty state has passed for a certain period of time (transmission cycle = 8 ms) or more). If there is no free space in the send data buffer 718 or if a certain period of time has not passed since the send data buffer 718 became free, "0" (off) is set to "buffer empty 2" (bit 2). If a certain period of time has passed since the transmission data buffer 718 became empty, "1" (on) is set in "buffer empty 2" (bit 2). Note that the condition for setting "buffer empty 2" (bit 2) in the status register T to "1" (on) is a certain period of time (transmission period) after the last transmission of the information stored in the transmission data buffer 718. = 8 ms) or more, and the free capacity of the transmission data buffer 718 is equal to or larger than the maximum number of bytes for one packet (32 bytes).

“Buffer Full” (bit 3) in the status register T stores information as to whether or not there is space for one or more packets in the transmission data buffer 718. If there is space for one or more packets in the transmission data buffer 718, "0" (off) is set to "buffer full" (bit 3), and there is no space for one or more packets in the transmission data buffer 718 (no space available). If there is less than one packet), "1" (on) is set to "buffer full" (bit 3).

Note that the conditions for setting "buffer full" (bit 3) to "1" (on) include the following various conditions.
(1) When the free space in the send data buffer 718 is less than the maximum number of bytes for one packet (32 bytes) (2) When the free space in the send data buffer 718 is less than the predetermined number (16 bytes) (3) Send A state in which 256 bytes of data have been written to the data buffer 718 (4) When the free capacity of the send data buffer 718 is less than the minimum number of bytes for one packet (2 bytes)

In the third gaming machine, condition (1) is the condition for setting the buffer full (bit 3) to "1" (on), but as status information, conditions (1) to (4) are individually bits may be assigned to For example, a status register T2 is provided in addition to the status register T, and condition (1) is assigned to bit 0 of status register T2, condition (2) is assigned to bit 1, condition (3) is assigned to bit 2, and condition (4) is assigned to bit 1. ) may be assigned to bit 3. In this case, if any of conditions (1) to (4) is met, "1" (on) is set to "buffer full" (bit 3) of status register T, and then "1" (on) is set to "buffer full" (bit 3) of status register T2. "1" (on) is set in the bits corresponding to the conditions (1) to (4) that have occurred. If such a configuration is adopted, for example, the main CPU will not be able to handle the size of the gaming control data that it wants to send even if the "buffer full" (bit 3) in the status register T is set to "1" (on). If it is 2 bytes, even if bits 0 (condition 1) to 2 (condition 3) in status register T2 are set to "1" (on), bit 3 (condition 4) will be "0" (off). If so, game control data can be written to the transmission data buffer 718.

“Transfer error” (bit 4) in the status register T stores information as to whether an error has occurred (transfer abnormality exists) in transferring (writing) data to the transmit data buffer 718. . If there is no transfer error, "0" (off) is set to "transfer error" (bit 4), and if there is a transfer error, "1" (on) is set to "transfer error" (bit 4). is set to Note that if the game control data is written in a state where there is an abnormality in the transmission data buffer 718, a transfer abnormality will occur and the "transfer error" (bit 4) will be set to "1" (on). Furthermore, even if there is no abnormality in the transmission data buffer 718, if gaming control data is written with the "access protect" (bit 5) in the status register T set to "1" (on), Also, the “transfer error” (bit 4) is set to “1” (on).

In the "access protect" (bit 5) in the status register T, information for restricting access to the transmission data buffer 718 is set (written) by the host (main CPU in the third gaming machine). If access is not possible, "0" (off) is set to "access protect" (bit 5), and if access is allowed, "1" (on) is set to "access protect" (bit 5). be done. Note that when the host (main CPU) confirms (Read) whether access to the transmission data buffer 718 is possible or not, the information of "access protect" (bit 5) in the status register T is In a gaming machine, the data is read out by the main CPU (main CPU).

In addition, "active" (bit 6) in the status register T contains information on whether transmission to the transmission data buffer 718 is enabled (transmission canceled) or disabled (transmission prohibited). ) is set (Write). If transmission is prohibited, "active" (bit 6) is set to "0" (off), and if transmission is canceled, "active" (bit 6) is set to "1" (on). . Note that when the host (main CPU) confirms (Read) the validity/invalidity of transmission to the transmission data buffer 718, the information of "active" (bit 6) in the status register T is In a gaming machine, the data is read out by the main CPU (main CPU). In addition, when the main CPU is powered on (recovery from power failure), it sets "active" (bit 6) in the status register T to "0" (off) for a certain period of time (the time required to start up the sub CPU 615). Immediately before returning the state of the main control unit 600 to the state before the power outage, "active" (bit 6) is set to "1" (on) to stabilize the startup of the sub CPU 615.

As shown in FIG. 129B, in the status register R, as information regarding the reception status, information called "buffer ready" is set to bit 0, information called "buffer empty" is set to bit 1, and information called "buffer full" is set to bit 1. ” is set in bit 2, “transfer error” is set in bit 3, “reception error” is set in bit 4, and “access protection” is set in bit 5. and information called "active" is set in bit 6. Note that bit 7 of status register R is unused.

Note that in the third gaming machine, confirmation (reading) and setting (writing) of various information related to the reception status stored in the status register R can be executed by the sub CPU 615 that serves as the host of the reception operation. However, the sub CPU 615 can only check (read) bits 0 to 4 in status register R (see "R/-" notation in FIG. 129B), but bits 5 to 6 Both confirmation (reading) and setting (writing) can be performed for (see the "R/W" notation in FIG. 129B).

“Buffer Ready” (bit 0) in the status register R stores information on the acceptance state of data transfer (writing) to the reception data buffer 721. If it cannot be accepted, "0" (off) is set to "buffer ready" (bit 0), and if it is acceptable, "1" (on) is set to "buffer ready" (bit 0). be done.

“Buffer Empty” (bit 1) in the status register R stores information about the state of the receive data buffer 721 (whether it is empty or not). When there is one packet (or one byte) or more of data in the reception data buffer 721, “0” (off) is set to “buffer empty” (bit 1), and one packet (or one byte) is stored in the reception data buffer 721. If there is no data (byte), "1" (on) is set to "buffer empty" (bit 1).

“Buffer full” (bit 2) in the status register R stores information as to whether or not there is space for one or more packets in the receive data buffer 721. If there is space for one or more packets in the reception data buffer 721, "0" (off) is set to "buffer full" (bit 2), and there is no space for one or more packets in the reception data buffer 721 (no space available). If there is less than one packet), "1" (on) is set to "buffer full" (bit 2).

“Transfer error” (bit 3) in the status register R stores information as to whether an error has occurred (transfer abnormality exists) in transferring (writing) data to the receive data buffer 721. . If there is no transfer error, "0" (off) is set to "transfer error" (bit 3), and if there is a transfer error, "1" (on) is set to "transfer error" (bit 3). is set to

"Reception error" (bit 4) in the status register R stores information as to whether an error has occurred during reception (reception abnormality exists) or not. If there is no reception error, "0" (off) is set to "reception error" (bit 4), and if there is a reception error, "1" (on) is set to "reception error" (bit 4). is set to "Reception errors" (bit 4) include, for example, parity errors, framing errors, and overrun errors that may occur each time one byte of data is received, as well as errors caused by the CRC16 check circuit after receiving one packet of data. There are reception abnormalities such as CRC errors that can be detected, and when any one of these reception abnormalities occurs, "1" (on) is set in "reception error" (bit 4). Note that if there is no parity error, framing error, or overrun error in all of the received data (gaming control data) for one packet, the error detection code data (CRC) is checked by a CRC16 check circuit.

In the "access protect" (bit 5) in the status register R, information for restricting access to the reception data buffer 721 is set (written) by the host (sub CPU 615 in the third gaming machine). If access is not possible, "0" (off) is set to "access protect" (bit 5), and if access is allowed, "1" (on) is set to "access protect" (bit 5). be done. Note that when the host (sub CPU 615) confirms (Read) whether access to the reception data buffer 721 is enabled or disabled, the information of "access protect" (bit 5) in the status register R is In the gaming machine, it is read out by the sub CPU 615).

In addition, "active" (bit 6) in the status register R contains information on whether reception is enabled (cancels reception) or disabled (inhibits reception) to the reception data buffer 721. ) is set (Write). When reception is prohibited, "0" (off) is set to "active" (bit 6), and when reception is canceled, "1" (on) is set to "active" (bit 6). . Note that when the host (sub CPU 615) confirms (Read) whether transmission to the receive data buffer 721 is enabled or disabled, the information of "active" (bit 6) in the status register R is In the gaming machine, it is read out by the sub CPU 615).

Note that when the host (sub CPU 615 in the third game machine) sets "active" (bit 6) in status register R to "0" (off), the "O_RX" terminal receives transmission data from the host. Even if the received data is set in the receive shift register 720, the received data is not written to the receive data buffer 721. Furthermore, in this case, the option check circuit also does not operate.

Although not shown in FIG. 128, the third gaming machine also includes a transmission data counter for counting the number of 1-byte transmission data and a transmission data counter for counting the number of 1-byte reception data in the asynchronous serial communication circuit 702. A received data counter is provided for counting.

The transmission data counter is incremented by 1 each time 1 byte of data is written to the transmission data buffer 718, and 1 byte of data is transmitted (data is set in the transmission shift register 719 or data is transmitted from the transmission shift register 719). 1 is subtracted each time. The main CPU serving as the host can check the usage status of the transmission data buffer 718 by referring to the value of the transmission data counter, and can determine whether an overflow of the transmission data buffer 718 has occurred. Note that the transmission data read from the transmission data buffer 718 is erased from the transmission data buffer 718 at the time it is read (set in the transmission shift register 719).

The receive data counter receives data in units of 1 byte (sets data in the receive shift register 720 or receives data in the receive shift register 720) and writes 1 byte to the receive data buffer 721. Each time data is read from the reception data buffer 721 via the data read register 713 in 1-byte units, 1 is subtracted. The sub CPU 615 serving as the host can determine whether or not there is reception data by referring to the reception data counter and grasping whether there is reception data in the reception data buffer 721. Note that the reception data read out from the reception data buffer 721 is erased from the reception data buffer 721 at the time it is read out.

The transmission data counter is also used to set bit 1 (B1) to bit 3 (B3) of status register T (Fig. 129A) to "1" (on) or "0" (off). The data counter is also used to set bit 1 (B1) and bit 2 (B2) of status register R (FIG. 129B) to "1" (on) or "0" (off).

(baud rate generation circuit)
The baud rate generation circuit 715 divides the frequency of the clock signal (CLK) supplied to the HB-LSI 700, and generates baud rates for transmission and reception from the divided clock signal. The baud rate generation circuit 715 is also provided with a baud rate setting register T in which the generated transmission baud rate is set (stored), and a baud rate setting register R in which the generated reception baud rate is set. The transmission baud rate set in the baud rate setting register T is supplied to the transmission shift register 719, and the reception baud rate set in the baud rate setting register R is supplied to the reception shift register 720.

(Optional provision/check circuit)
The option grant/check circuit 716 includes an option grant circuit and an option check circuit.

The option provision circuit provides start data (STX) and end data (ETX) to one packet of game control data group transmitted from the asynchronous serial communication circuit 702. Further, the option provision circuit performs DLE control (conversion) according to the gaming control data to generate converted gaming control data, and also provides DLE data (7DH) to the converted gaming control data. Furthermore, the option provision circuit provides error detection code data (CRC16) generated by a CRC16 generation circuit (described later) to one packet of game control data group to be transmitted.

The option check circuit performs a process of checking (discriminating) start data (STX) and end data (ETX) from the data received by the asynchronous serial communication circuit 702. In addition, the option check circuit performs processing to check whether the gaming control data received by the asynchronous serial communication circuit 702 is DLE data (7DH), and if DLE data (7DH) is detected in the checking processing, , the gaming control data received next to the DLE data (gaming control data subjected to DLE control (conversion)) is restored to the original gaming control data. Furthermore, when the option check circuit detects error detection code data (CRC16) from the data received by the asynchronous serial communication circuit 702, it checks the error detection code data (CRC16) against a CRC16 check circuit (described below). Judgment) Request processing.

(CRC16 generation/check circuit)
The CRC16 generation/check circuit 717 includes a CRC16 generation circuit and a CRC16 check circuit.

The CRC16 generation circuit generates 2-byte error detection code data (CRC16: error detection data) using one packet of gaming control data group to be transmitted (gaming control data group written in the transmission data buffer 718). calculate. In the third gaming machine, as will be described later, if the gaming control data group includes gaming control data subject to DLE control, the gaming control data before DLE control (conversion) is not written in the transmission data buffer 718. However, game control data after DLE control (conversion) is not written. Therefore, in the third gaming machine, even if the gaming control data group includes gaming control data subject to DLE control, the error detection code data (CRC16) is Generated using the game control data group.

Note that the present invention is not limited to this, and when the game control data group includes game control data that is subject to DLE control, one packet of game control data group (DLE Error detection code data (CRC16) may be generated using a game control data group including game control data and DLE data (7DH) after control (conversion) (see FIG. 140B described later). Furthermore, error detection code data (CRC16) may be generated including not only one packet of game control data group to be transmitted, but also start data (STX) and end data (ETX).

The CRC16 check circuit generates 2-byte error detection code data (CRC16) using the received one packet of gaming control data group (gaming control data written in the received data buffer 721), and uses the generated error detection code. The data is compared with the received 2-byte error detection code data, and based on the comparison result, the presence or absence of reception abnormality is set. When the CRC16 check circuit detects a reception abnormality (CRC error), it sets "reception error" (bit 4) in the status register R to "1". Furthermore, even if the CRC16 check circuit does not detect any reception abnormality, if the "reception error" (bit 4) in the status register R is already set to "1", the CRC16 check circuit will check the 1” is retained.

In addition, in the third gaming machine, an example will be described in which CRC (cyclic redundancy check) is used as a method for checking abnormalities that occur with data communication (transfer), but the present invention is not limited to this, and the game control data group Any check method that can detect communication abnormalities can be adopted. For example, as a method for checking communication abnormality, a sum value may be used, or a method using a combination of CRC and sum value may be used.

(Transmit data buffer, transmit shift register, receive shift register, receive data buffer)
The transmission data buffer 718 stores game control data written by the host (main CPU in the third gaming machine) via the first data set register 711 and the second data set register 712. In the third gaming machine, the capacity of the transmission data buffer 718 is assumed to be 256 bytes. Note that the value of the above-mentioned transmission data counter is incremented by 1 each time 1 byte of game control data is written to the transmission data buffer 718.

Note that the transmission data buffer 718 does not store start data (STX), end data (ETX), and error detection code data (CRC16) that are added to one packet of gaming control data group to be transmitted. Further, in the third gaming machine, the transmission data buffer 718 stores gaming control data before DLE control (conversion), but does not store DLE data and gaming control data after DLE control (conversion). The game control data subject to DLE control stored in the transmission data buffer 718 is subjected to DLE control by the option provision circuit at the time of transmission of the game control data, and the generated DLE data and the game control data after DLE control (conversion) is set directly in the transmission shift register 719. Similarly, start data (STX), end data (ETX), and error detection code data (CRC16) are not stored in the transmission data buffer 718, but are set in the transmission shift register 719 by the option provision circuit.

The transmission shift register 719 is composed of a 1-byte long shift register. Data to be transmitted to the outside by the asynchronous serial communication circuit 702 is set in the transmission shift register 719 . The data set in the transmission shift register 719 is then transmitted to the outside via the "O_TX" terminal (transmission terminal) of the HB-LSI 700 to which the asynchronous serial communication circuit 702 is connected.

The reception shift register 720 is composed of a 1-byte long shift register. Data received via the “O_RX” terminal (reception terminal) of the HB-LSI 700 to which the asynchronous serial communication circuit 702 is connected is set in the reception shift register 720.

The reception data buffer 721 stores game control data written by the reception shift register 720. In the third gaming machine, the capacity of the reception data buffer 721 is assumed to be 256 bytes.

Note that the reception data buffer 721 does not store the start data (STX), end data (ETX), and error detection code data (CRC16) given to the gaming control data group of one packet to be received. Further, in the third gaming machine, the received DLE data and the game control data after DLE control (conversion) are not stored in the received data buffer 721. When the received data set in the reception shift register 720 is DLE data, the received data (gaming control data) next to the DLE data is restored to the gaming control data before DLE control (conversion), and the restored data is The received game control data is stored in the received data buffer 721.

Note that in the third gaming machine, reception packet data counters (not shown) that store (count) the data size of one packet written to the reception data buffer 721 are provided for the number of packets written to the reception data buffer 721. It will be done. For example, when three packets of game control data are written to the reception data buffer 721, three reception packet data counters are provided. Then, the reception packet data counter starts counting at the timing when the start data (STX) is received (the reception packet data counter is set to "0"), and the end data (ETX) is set in the reception shift register 720. At the point in time, the number of times (number of bytes) that game control data has been written is set in the received data buffer 721. Note that the above-described transmission data counter, reception data counter, multiple transmission packet data counters, and multiple reception packet data counters are stored in the RAM (not shown) in the HB-LSI 700 or the RAM (not shown) in the asynchronous serial communication circuit 702. ).

(Transmission operation in asynchronous serial communication circuit)
Here, the data transmission operation performed by the asynchronous serial communication circuit 702 will be explained. In the third game machine, an HB-LSI 700 (first HB-LSI 611) built in the main control unit 600 is used instead of using the asynchronous serial communication circuit (SCU) built in the main CPU (microprocessor 610). Game control data (command data) is transmitted from the main control section 600 to the sub control section 620.

When transmitting data from the asynchronous serial communication circuit 702 to the outside, the start data (STX), end data, and data (ETX) and error detection code data (CRC16), and performs DLE control on some gaming control data of the gaming control data group as necessary. Thereafter, the transmission data is sequentially set in the transmission shift register 719, and the data is transmitted to the outside (the sub-control unit 620 in the third gaming machine).

Specifically, first, at the start of transmission, before transmitting the first game control data stored in the transmission data buffer 718, the option provision circuit sets start data (STX) in the transmission shift register 719 and transmits it. do. Next, the option provision circuit sets the error detection code data (CRC16) generated by the CRC16 generation circuit in the transmission shift register 719 and transmits it.

Next, game control data is set in the transmission shift register 719 and transmitted sequentially (according to the transmission order) from the first game control data stored in the transmission data buffer 718. At this time, if the game control data in the transmission data buffer 718 is DLE data (7DH), start data (7EH), or end data (7FH), the option provision circuit to perform DLE control (conversion), set the DLE data in the transmission shift register 719 and transmit it, and then set the gaming control data after the DLE control (conversion) in the transmission shift register 719 and transmit it.

Then, the last game control data is stored in the transmission data buffer 718 (the value of the corresponding transmission packet data counter changes from "1" to "0"), and the last game control data is set in the transmission shift register 719. After the end data (ETX) is transmitted, the option granting circuit sets the end data (ETX) in the transmission shift register 719 and transmits it.

In addition, if one or more packets of game control data are stored in the transmission data buffer 718, the above-mentioned transmission operation is performed to transmit the game control data in units of packets in the order in which they are stored in the transmission data buffer 718, at 8 ms intervals. group (command data) is sent.

(Reception operation in asynchronous serial communication circuit)
Next, a data receiving operation performed by the asynchronous serial communication circuit 702 will be described. When data is received by the asynchronous serial communication circuit 702, a data type check process (discrimination process) is performed on the received data set in the receive shift register 720. In this check process, if the received data is game control data, the game control data is written to the reception data buffer 721 (the values of the reception data counter and reception packet data counter are incremented by 1), but the reception data starts. In the case of data (STX), end data (ETX), and error detection code data (CRC16), these data are not written to the reception data buffer 721. Furthermore, at this time, if the received data set in the receive shift register 720 is DLE-controlled gaming control data, the restored gaming control data is written into the received data buffer 721.

Specifically, at the start of reception, the option check circuit first checks whether or not the received data set in the reception shift register 720 (1-byte reception) is start data (STX). , if it is start data (STX), then the CRC16 check circuit acquires 2 bytes of received data set in the reception shift register 720 as error detection code data (CRC16).

Next, the reception data set in the reception shift register 720 after receiving the error detection code data (CRC16) is sequentially written into the reception data buffer 721 as gaming control data. At this time, if the received data set in the receive shift register 720 is DLE data (7DH), the option check circuit performs DLE restoration processing on the received data set in the receive shift register 720 next. and writes the restored game control data into the received data buffer 721.

Then, when the option check circuit detects that the received data set in the receive shift register 720 is end data (ETX), the CRC16 check circuit generates a CRC16 from the gaming control data group stored in the received data buffer 721. A circuit is used to generate error detection code data (CRC16), and the generated error detection code data (CRC16) is compared with error detection code data (CRC16) acquired via the reception shift register 720.

Next, if the comparison result between the generated error detection code data (CRC16) and the received error detection code data (CRC16) is normal, the reception data buffer 721 is counted starting with the reception of the start data (STX). The number of times (number of bytes) that game control data is written to is set as the size of one packet, and the size is set in the corresponding received packet data counter. On the other hand, if the verification result is not normal, the game control data written in the reception data buffer 721 is discarded, and bit 4 ("reception error") of the status register R (see FIG. 129B) is set to "1" (on). set.

[11-3-2. Internal configuration of random number generation circuit]
Next, the internal configuration of the random number generation circuit 708 provided in the HB-LSI 700 will be explained. FIG. 130 is a block diagram showing the internal configuration of random number generation circuit 708.

As shown in FIG. 130, the random number generation circuit 708 includes four 16-bit random number generation circuits (a first random number generation circuit 731, a second random number generation circuit 732, a third random number generation circuit 733, and a fourth random number generation circuit 734). , a random number circuit selection circuit 735, a random number register 736, a random number latch register 737, and a random number monitoring circuit 738 (random number monitoring section).

The first random number generation circuit 731, the second random number generation circuit 732, the third random number generation circuit 733, and the fourth random number generation circuit 734 are all circuits that generate 16-bit random numbers. Each random number generation circuit is operated by a clock signal (CLK) externally supplied to the HB-LSI 700, and generates a random number at the cycle of the clock signal. Here, an example will be described in which four 16-bit random number generation circuits (first random number generation circuit 731 to fourth random number generation circuit 734) are provided in one HB-LSI 700 (random number generation circuit 708), but the present invention is not limited to this. For example, depending on the mounting space of the HB-LSI 700, an even number of 16-bit random number generation circuits such as 2, 8, 16, etc. may be provided in one HB-LSI 700 (random number generation circuit 708). .

The random number circuit selection circuit 735 is a circuit that selects one 16-bit random number generation circuit from four 16-bit random number generation circuits (first random number generation circuit 731 to fourth random number generation circuit 734). Further, the random number circuit selection circuit 735 is connected to four 16-bit random number generation circuits (first random number generation circuit 731 to fourth random number generation circuit 734) and a random number register 736, and the random number circuit selection circuit 735 is connected to four 16-bit random number generation circuits (first random number generation circuit 731 to fourth random number generation circuit 734) and a random number register 736. A bit random value is set in the random number register 736.

The random number circuit selection circuit 735 operates according to a clock signal (CLK) externally supplied to the HB-LSI 700, and selects four 16-bit random number generation circuits (first random number generation circuit 731 to fourth random number generation circuit 731 to generation circuit 734). Although not shown in FIG. 130, the random number circuit selection circuit 735 is provided with a selection counter that is referenced in the selection switching operation, and the value of the selection counter is determined by a clock signal (CLK) supplied from the outside. Updated within the range of 0 to 65535. Then, the random number circuit selection circuit 735 selects one 16-bit random number generation circuit from the four 16-bit random number generation circuits based on the value of the selection counter updated by the clock signal.

The random number register 736 is a 16-bit long register, and stores a 16-bit random value generated by one 16-bit random number generation circuit selected by the random number circuit selection circuit 735.

Random number latch register 737 latches the value of random number register 736. The random number can be latched by writing a random value into the address area in the main RAM (see FIG. 131 described later) assigned to the random number latch register 737, or by writing the address in the main RAM assigned to the random number register 736. By reading, the value of the random number register 736 is latched, and a random value is obtained from the random number register 736. Further, the latch is released by writing a random value to the address area in the main RAM assigned to the random number latch register 737. Note that in the third gaming machine, the random number value (value of the random number register 736) latched by the random number generation circuit 708 of the first HB-LSI 611 is obtained by the main CPU (obtained in S4 in FIG. 23, etc.), and this random number value is is used in the internal winning combination lottery (S64 in FIG. 26, etc.).

Random number monitoring circuit 738 monitors the operating state of random number generation circuit 708. Specifically, the random number monitoring circuit 738 is connected to four 16-bit random number generation circuits (the first random number generation circuit 731 to the fourth random number generation circuit 734) and the random number circuit selection circuit 735, and is connected to the four 16-bit random number generation circuits generation state, the state of the clock signal (CLK) supplied to the four 16-bit random number generation circuits, the selection state of the random number circuit selection circuit 735, and the state (frequency) of the clock signal supplied to the random number circuit selection circuit 735. to monitor.

The random number monitoring circuit 738 is provided with a random number status register, and each bit of the random number status register stores each piece of monitoring information as a status. In addition, in the third gaming machine, the main CPU can read the information stored in the random number status register in the first HB-LSI 611 from the main RAM address assigned to the random number status register. The operating state of the random number generation circuit 708 can be grasped.

The random number monitoring circuit 738 includes a clock generation circuit (independent) that generates a clock signal (CLK) to be supplied to the four 16-bit random number generation circuits (first random number generation circuit 731 to fourth random number generation circuit 734) and the random number circuit selection circuit 735. It operates using a clock signal generated by a clock generation circuit different from the one shown in the figure.

If the source of the clock signal for the random number monitoring circuit 738 is the same as the source of the clock signal for the four 16-bit random number generation circuits and the random number circuit selection circuit 735, then the four 16-bit random number generation circuits and If a clock abnormality occurs in the random number circuit selection circuit 735 and the clock generation circuit stops, the operation of the random number monitoring circuit 738 will also stop, so this is to prevent such a problem from occurring. Therefore, the period (frequency) of the clock signal supplied to the random number monitoring circuit 738 may be longer (lower) than the period (frequency) of the clock signal supplied to the four 16-bit random number generation circuits and the random number circuit selection circuit 735. good. For example, if the frequency of the clock signal supplied to the four 16-bit random number generation circuits and the random number circuit selection circuit 735 is approximately 9 MHz, the frequency of the clock signal supplied to the random number monitoring circuit 738 can be approximately 3 MHz. . Furthermore, the clock generation circuit may be provided within the random number generation circuit 708, or may be configured to supply a clock signal from outside.

Note that the types of abnormalities that occur in the random number generation circuit 708 include the following.
(1) When the random value generated from the 16-bit random number generation circuit is not updated for a certain period of time or more (circuit abnormality)
(2) When the clock signal (CLK) is constantly counted and the count cannot be updated for a certain period of time (abnormal clock frequency)
(3) When the clock signal (CLK) is constantly counted and the clock signal count takes a long time longer than a certain threshold (specific period) to update (decrease in clock signal frequency)

When the above abnormality occurs in the random number generation circuit 708, the abnormality bit and the abnormality history bit in the random number status register are set to the on state (“1”). In addition, when a "circuit abnormality" or "clock frequency abnormality" occurs, the host (main CPU in the case of the third gaming machine) performs processing corresponding to a serious error (error information "88" or ``rr'' is displayed), all gaming operations are stopped, and the game waits until the power is turned off. On the other hand, if a "decrease in clock signal frequency" occurs, the host (main CPU in the case of the third gaming machine) waits until the clock signal frequency returns to normal, and resumes gaming operations when the frequency returns to normal. . Note that in the random number monitoring circuit 738, when a "decrease in clock signal frequency" occurs, if the frequency returns to normal, the abnormal bit in the random number status register returns to the off state ("0"), but the abnormal bit in the random number status register The on state is maintained until the power is cut off. Specifically, the host (the main CPU in the third gaming machine) executes the process at a fixed period (for example, the period of periodic interrupt processing performed by the main CPU (1.1172 ms)), or at the start or end of a unit game. At this point, the information of each bit of the random number status register is referred to, and the processing when an abnormality occurs in the random number generation circuit 708 described above is performed. Note that the present invention is not limited to this, and for example, until the random number generation circuit 708 returns to a normal state, a random number generation circuit (not shown) built in the microprocessor 610 generates a random number used in the lottery process for internal winning combinations. A numerical value may also be obtained.

[11-4. Main control board configuration]
Next, the internal configuration of the main control board 601 will be explained. FIG. 131 is a diagram showing the internal configuration of the main control board 601 and the connection relationship between the main control board 601 and external boards and peripheral devices.

As shown in FIG. 131, the main control board 601 includes a microprocessor 610, a first HB-LSI 611, a role ratio monitor device 54 (4-digit 7-segment LED), a sight test circuit 605, and interconnects these parts. and a bus 606 for connection.

Further, the main control board 601 is provided with an optical communication output connector A, an optical communication input connector B, and an optical communication output connector C that enable connection to an external board using an optical fiber cable. Note that the optical communication output connector A and the optical communication output connector C are electrical-optical conversion connectors that convert an electrical signal into an optical signal and output it, and the optical communication input connector B converts an optical signal into an electrical signal. This is a photoelectric conversion connector that outputs

The microprocessor 610 (gaming control means) is a microprocessor with a security function used in conventional gaming machines. Therefore, although the internal configuration of the microprocessor 610 will not be described in detail here, the microprocessor 610 includes a main CPU (computation processing unit), a main ROM (first storage unit), and a main RAM (second storage unit). part), external bus I/F, clock circuit, reset controller, arithmetic circuit, random number circuit, parallel port, interrupt controller, timer circuit, multiple asynchronous serial communication circuits, and signal buses that connect these parts to each other. It is provided.

The test shot test circuit 605 is a circuit used for a certification test (sight test) of a pachi-slot machine. Note that the electronic components of the test firing test circuit 605 are mounted on the main control board 601 for application (certification test), but not on the main control board 601 for release (product version). However, since the same board is used for the main control board 601 for application and for release, the mounting pattern of the electronic components of the sight test circuit 605 remains on the main control board 601 for release (product version).

Note that the role ratio monitor device 54 is composed of a four-digit 7-segment LED, and is mounted on the main control board 601. The configuration of the winning ratio monitor device 54 is the same as that explained in FIG. 3, and the content displayed on the winning ratio monitoring device 54 is also the same as that explained in <Example of stored data> in FIG. , these descriptions will be omitted here. Furthermore, since the configuration of the first HB-LSI 611 is the same as that of the HB-LSI 700 described with reference to FIG. 127, a description of the configuration will be omitted here.

Next, the connection relationships between the components mounted on the main control board 601 and the connections between each component and external boards and peripheral devices will be described.

(Connection mode of microprocessor)
Between the microprocessor 610 and the first HB-LSI 611, an external bus I/F built in both is connected by a bus 606 including an address bus and a data bus, and data is input and output in both directions. The winning ratio monitoring device 54 and the sighting test circuit 605 are connected to a microprocessor 610 via a bus 606, and the microprocessor 610 can output data to the winning ratio monitoring device 54 and the sighting testing circuit 605. Further, the test shot test circuit 605 is connected via a control signal line to a first interface board 301 (relay board) for a test machine used for a certification test (sight test) of a pachi-slot machine, and the test shot test circuit 605 and test machine It is possible to output data to and from the first interface board 301.

The “SCU (Serial Communication Unit) 2_T” terminal (transmission terminal) of the microprocessor 610, which is connected to a predetermined asynchronous serial communication circuit (not shown) built into the microprocessor 610, is connected to the It is connected to the second interface board 302 or the third interface board 303 for the testing machine via a control signal line. Then, between the microprocessor 610 and the second interface board 302 for the test machine or the third interface board 303 for the test machine, the microprocessor 610 (predetermined asynchronous serial communication circuit) is connected to the test machine. Data is transmitted in one direction to the second interface board 302 for the test machine or the third interface board 303 for the test machine.

Furthermore, if the third gaming machine is a medalless gaming machine, the "SCU0_T" terminal (transmission terminal) of the microprocessor 610 is connected to a specific asynchronous serial communication circuit (not shown) built into the microprocessor 610. and “SCU0_R” terminal (receiving terminal) are connected to the medal number control board 650 via a control signal line. Data is exchanged bidirectionally between the microprocessor 610 (specific asynchronous serial communication circuit) and the medal number control board 650 by asynchronous serial communication. Note that when the main control board 601 and the medal number control board 650 are placed close to each other, or when both boards are connected using a BtoB (Board to Board) connector, an external Data can be input and output using a memory mapped IO method via an I/F and a bus (including an address bus and a data bus).

(“PO0” to “PO6” terminals of the 1st HB-LSI)
“PO0” to “PO6” terminals (output terminals) of the first HB-LSI 611 connected to the built-in PIO circuit 705 of the first HB-LSI 611 are connected to the external centralized terminal board 55 via control signal lines. Note that the first HB-LSI 611 and the external centralized terminal board 55 are actually connected in parallel by seven control signal lines, but in FIG. 131, the explanation is simplified and the seven control signal lines are The line is indicated by a single thick arrow.

Between the PIO circuit 705 built into the first HB-LSI 611 and the external centralized terminal board 55, data is output in one direction from the PIO circuit 705 to the external centralized terminal board 55. The signals output from each of the "PO0" to "PO6" terminals of the first HB-LSI 611 are as follows.

The signal output from the "PO0" terminal is a medal insertion signal, and is turned on for a certain period of time in response to a bet operation (operation on the MAX bet button 6a, operation on the 1 bet button 6b, and medal insertion operation). Note that if the bet operation is an operation on the 1-bet button 6b or an operation to insert one medal, a pulse signal that remains on for a certain period of time is output from the "PO0" terminal for each operation. On the other hand, when the bet operation is an operation on the MAX bet button 6a, pulse signals corresponding to the number of game values newly bet by the operation are output from the "PO0" terminal. For example, when the number of bets is "0" and the number of game values "3" is newly bet (betted) by operating the MAX bet button 6a, three pulse signals are sent to the "PO0" terminal at predetermined intervals. For example, when the number of bets is "1" and a new gaming value number "2" is placed by operating the MAX bet button 6a, two pulse signals are output from the "PO0" terminal at a predetermined interval. For example, when the number of bets is "2" and a new bet of "1" is made by operating the MAX bet button 6a, one pulse signal is output from the "PO0" terminal. Ru.

The signal output from the "PO1" terminal is a medal payout signal, and is a signal output in response to a credit up operation (addition operation of the number of credits) and a medal payout operation. Specifically, when a credit up operation (addition of the number of credits) and a medal payout operation are performed, a pulse signal that remains on for a certain period of time is output from the "PO1" terminal for the number of times equal to the number of payouts (the number of credits up). Output.

The signal output from the "PO2" terminal is external signal 1 (a signal indicating the gaming status of RB, BB, or RT), and the signal changes depending on the gaming (balls put out) specifications of the gaming machine. . The signal output from the "PO3" terminal is external signal 2 (a signal indicating the gaming status of RB, BB, or RT), and the signal changes depending on the gaming (balls put out) specifications of the gaming machine. . The signal output from the "PO4" terminal is external signal 3 (a signal indicating the gaming status of RB, BB, or RT), and the signal changes depending on the gaming (balls put out) specifications of the gaming machine. .

Note that the types of gaming states indicated by external signal 1, external signal 2, and external signal 3 output from the "PO2" terminal, "PO3" terminal, and "PO4" terminal are different from each other. That is, if one predetermined output terminal among the "PO2" terminal, "PO3" terminal, and "PO4" terminal is set as the output terminal of the signal indicating the gaming state of RB, one of the remaining two output terminals The output terminal may be set as an output terminal for a signal indicating the gaming state of BB, and the other output terminal may be set as an output terminal for a signal indicating the gaming state of RT. In addition, depending on the gaming (ball output) specifications of the gaming machine, any one output terminal or any two of the "PO2" terminal, "PO3" terminal, and "PO4" terminal may output a signal indicating the gaming status. It may also be set as an output terminal.

The signal output from the "PO5" terminal is external signal 4 (security signal or door open signal). When the "PO5" terminal is the output terminal for the security signal, when the main CPU of the main control unit 600 detects an error, the external signal 4 changes from OFF to ON, and the "PO5" terminal becomes the output terminal for the door open signal. When this is the case, the external signal 4 is turned on (open) or off (closed) depending on the state of the door opening/closing monitoring switch 56. The signal output from the "PO6" terminal is an external signal 5 (security signal or door open signal). When the "PO6" terminal is the output terminal for the security signal, when the main CPU of the main control unit 600 detects an error, the external signal 5 changes from OFF to ON, and the "PO6" terminal becomes the output terminal for the door open signal. When this is the case, the external signal 5 is turned on (open) or off (closed) depending on the state of the door opening/closing monitoring switch 56.

Note that the types of signals indicated by the external signal 4 and the external signal 5 output from the "PO5" terminal and the "PO6" terminal, respectively, are different from each other. That is, among the "PO5" terminal and the "PO6" terminal, one output terminal is set as an output terminal for a security signal, and the other output terminal is set as an output terminal for a door open signal. Furthermore, in a specification in which the door open signal is included in the security signal, one of the "PO5" and "PO6" terminals is used, and the other is unused. In this configuration, when the main CPU of the main control unit 600 detects an error or when the door opening/closing monitoring switch 56 detects the door open (on) state, one of the "PO5" terminal and the "PO6" terminal The external signal to be output turns on.

(“PI0” to “PI2” terminals of the 1st HB-LSI)
The “PI0” terminal (input terminal) of the first HB-LSI 611 connected to the PIO circuit 705 built into the first HB-LSI 611 is connected to a count sensor (not shown) provided in the hopper device 32 via a control signal line. Connected. Note that the count sensor is a sensor for counting medals discharged from the hopper device 32. The "PI1" terminal (input terminal) of the first HB-LSI 611 connected to the built-in PIO circuit 705 in the first HB-LSI 611 is connected to the medal auxiliary storage 33 provided near the hopper device 32 via a control signal line. It is connected to the medal auxiliary storage switch 33S (see FIG. 3).

Between the PIO circuit 705 built in the first HB-LSI 611 and the hopper device 32, data is output in one direction from the hopper device 32 to the PIO circuit 705. Specifically, the data of the count counted by the count sensor in the hopper device 32 is input to the "PI0" terminal of the first HB-LSI 611, and the data of the number of counts counted by the count sensor in the hopper device 32 is input to the "PI1" terminal of the first HB-LSI 611. A signal detected by the switch 33S is input.

The “PI2” terminal (input terminal) of the first HB-LSI 611, which is connected to the PIO circuit 705 built into the first HB-LSI 611, is connected to the setting key-type switch 52 via a control signal line. Between the PIO circuit 705 built into the first HB-LSI 611 and the setting key-type switch 52, data is output in one direction from the setting key-type switch 52 to the PIO circuit 705. Specifically, a signal indicating the state (on or off) of the setting key-type switch 52 is input to the "PI2" terminal of the first HB-LSI 611.

Note that port input/output of data using the "PO0" to "PO6" terminals and "PI0" to "PI2" terminals of the first HB-LSI 611 is performed by the main CPU via the bus 606 (address bus and data bus). Execution can be controlled using a memory mapped IO method.

(“S0” to “S2” terminals of 1st HB-LSI)
The “S0” terminal (main/sub switching terminal) of the first HB-LSI 611, which is connected to the PIO circuit 705 built into the first HB-LSI 611, is connected to the 5V power supply (set to on). is set as the main setting. The "S1" and "S2" terminals of the first HB-LSI 611, which are connected to the PIO circuit 705 built into the first HB-LSI 611, are connected to a 5V power supply (set to ON), and thereby the address of the first HB-LSI 611 is Settings (master settings) are performed. The connection mode of the master setting for the "S1" terminal and the "S2" terminal can be arbitrarily determined by the designer, etc., and the master setting may be performed with other connection modes (for example, all grounded). Good too.

(“OP_O” and “OP_I” terminals of 1st HB-LSI)
The “OP_O” terminal (transmission terminal) of the first HB-LSI 611 connected to the serial bus communication circuit 701 built into the first HB-LSI 611 is connected to the optical communication output connector A of the main control board 601 via a control signal line. The optical communication output connector A is connected to the optical communication input connector D of the reel device board 602 via an optical fiber cable. That is, the serial bus communication circuit 701 built into the first HB-LSI 611 is connected to the drum device board 602 via the optical communication output connector A of the first HB-LSI 611 and an optical fiber cable. Then, between the main control board 601 and the drum device board 602, transmission data (described later) is transmitted from the "OP_O" terminal of the first HB-LSI 611 in the main control board 601 to the drum device board 602 by synchronous serial communication. (see FIG. 144) is transmitted in one direction.

The “OP_I” terminal (reception terminal) of the first HB-LSI 611 connected to the built-in serial bus communication circuit 701 of the first HB-LSI 611 is connected to the optical communication input connector B of the main control board 601 via a control signal line. The optical communication input connector B is connected to the optical communication output connector G of the door relay board 603 via an optical fiber cable. That is, the serial bus communication circuit 701 built into the first HB-LSI 611 is connected to the door relay board 603 via the optical communication input connector B of the first HB-LSI 611 and the optical fiber cable. Then, between the main control board 601 and the door relay board 603, transmission data (described later in FIG. ) is sent in one direction.

(“O_TX” terminal of 1st HB-LSI)
The “O_TX” terminal (transmission terminal) of the first HB-LSI 611 connected to the asynchronous serial communication circuit 702 built into the first HB-LSI 611 is connected to the optical communication output connector C of the main control board 601 via a control signal line. The optical communication output connector C is connected to the optical communication input connector H of the sub-relay board 621 via an optical fiber cable. That is, the asynchronous serial communication circuit 702 built into the first HB-LSI 611 is connected to the sub-relay board 621 via the optical communication output connector C of the first HB-LSI 611 and the optical fiber cable. Then, between the main control board 601 and the sub-relay board 621, command data (described later in FIG. 137 ) is sent in one direction.

[11-5. Configuration of rotation drum device board]
Next, the internal configuration of the drum device board 602 will be explained. FIG. 132 is a diagram showing the internal configuration of the drum device board 602 and the connection relationship between the drum device board 602 and external boards and peripheral devices.

The drum device board 602 has a second HB-LSI 612, as shown in FIG. Note that the configuration of the second HB-LSI 612 is the same as that of the HB-LSI 700 described in FIG. 127, so a description of the configuration will be omitted here.

Further, the drum device board 602 is provided with an optical communication input connector D and an optical communication output connector E that enable connection to an external board using an optical fiber cable. The optical communication input connector D is a photoelectric conversion connector that converts an optical signal into an electrical signal and outputs it, and the optical communication output connector E is an electro-optical conversion connector that converts an electrical signal into an optical signal and outputs it. be.

Furthermore, the reel device board 602 is provided with a driver IC 741 for driving the left reel 3L, a driver IC 742 for driving the middle reel 3C, and a driver IC 743 for driving the right reel 3R. Note that the present invention is not limited to this, and each driver IC may be provided on the drum board (not shown: provided outside the drum device board 602) of the corresponding reel.

(“OP_I” and “OP_O” terminals of 2nd HB-LSI)
The “OP_I” terminal (reception terminal) of the second HB-LSI 612 connected to the built-in serial bus communication circuit 701 of the second HB-LSI 612 is connected to the optical communication input connector D of the drum device board 602 via a control signal line. The optical communication input connector D is connected to the optical communication output connector A of the main control board 601 via an optical fiber cable. That is, the serial bus communication circuit 701 built into the second HB-LSI 612 is connected to the main control board 601 via the optical communication input connector D of the drum device board 602 and an optical fiber cable. Between the drum device board 602 and the main control board 601, transmission data (described later) is sent from the main control board 601 to the "OP_I" terminal of the second HB-LSI 612 in the drum device board 602 by synchronous serial communication. (see FIG. 144) is transmitted in one direction.

The “OP_O” terminal (transmission terminal) of the second HB-LSI 612 connected to the built-in serial bus communication circuit 701 of the second HB-LSI 612 is connected to the optical communication output connector E of the drum device board 602 via a control signal line. The optical communication output connector E is connected to the optical communication input connector F of the door relay board 603 via an optical fiber cable. That is, the serial bus communication circuit 701 built into the second HB-LSI 612 is connected to the door relay board 603 via the optical communication output connector E of the drum unit board 602 and the optical fiber cable. Then, between the drum device board 602 and the door relay board 603, transmission data (described later) is transmitted from the "OP_O" terminal of the second HB-LSI 612 in the drum device board 602 to the door relay board 603 by synchronous serial communication. (see FIG. 144) is transmitted in one direction.

(“PO0” to “PO6” terminals of 2nd HB-LSI)
The "PO0" terminal (output terminal) of the second HB-LSI 612, which is connected to the PIO circuit 705 built into the second HB-LSI 612, is connected to the hopper device 32 (including the medal auxiliary storage 33) via the control signal line. be done. Between the drum device board 602 and the hopper device 32, data is output in one direction from the “PO0” terminal of the second HB-LSI 612 to the hopper device 32.

The data (signal) output from the PIO circuit 705 in the second HB-LSI 612 to the hopper device 32 is a drive signal for driving a motor (not shown) provided for dispensing medals from the hopper device 32. be. The on/off control of this drive signal is performed by the main CPU in the main control board 601. Specifically, the main CPU turns on the drive signal when performing control to dispense one medal, and turns off the drive signal when it detects that a count sensor (not shown) in the hopper device 32 has counted the medals. state. Then, the main CPU repeats the on/off control of this drive signal for the number of medals to be paid out. Note that the main CPU does not repeat the on/off control of this drive signal for the number of payouts of game value, but turns on this drive signal when controlling the payout of the first medal, and then turns on the drive signal when controlling the payout of the first medal. When controlling the payout, the drive signal may be turned off when a count sensor (not shown) in the hopper device 32 detects that the medals have been counted.

In addition, in FIG. 132, two control signal lines are connected from the hopper device 32 to the main control board 601, but one control signal line connects a count sensor (not shown) in the hopper device 32 to the main control board 601. 601, and the other control signal line connects the medal auxiliary storage switch 33S of the medal auxiliary storage 33 located near the hopper device 32 (see FIG. 3). This is a control signal line that connects to the PIO circuit 705 in the main control board 601.

The "PO1" terminal and "PO2" (output terminal) of the second HB-LSI612, which are connected to the built-in PIO circuit 705 in the second HB-LSI612, are connected to the driver IC 741 for driving the left reel 3L via the control signal line. The driver IC 741 is connected to the left reel 3L (first reel) via a control signal line. That is, the PIO circuit 705 built into the second HB-LSI 612 is connected to the left reel 3L via the driver IC 741.

Between the PIO circuit 705 built in the second HB-LSI 612 and the driver IC 741 for driving the left reel 3L, data is output in one direction from the "PO1" and "PO2" terminals of the second HB-LSI 612 to the driver IC 741. Between the driver IC 741 and the left reel 3L, data is output in one direction from the driver IC 741 to the left reel 3L.

The data (signal) output from the PIO circuit 705 of the second HB-LSI 612 to the driver IC 741 via the "PO1" terminal is an A-phase excitation signal for driving the stepping motor 51L of the left reel 3L, and is "PO2". The data (signal) outputted to the driver IC 741 via the `` terminal is a B-phase excitation signal for driving the stepping motor 51L of the left reel 3L. The driver IC 741 for driving the left reel 3L generates an A-bar phase (inverted phase) excitation signal from the input A-phase excitation signal, and sends the A-phase excitation signal and A-bar phase excitation signal to the left reel 3L. Output. In addition, the driver IC 741 for driving the left reel 3L generates a B-bar phase (inverted phase) excitation signal from the input B-phase excitation signal, and sends the B-phase excitation signal and B-bar phase excitation signal to the left reel 3L. Output to 3L. In addition, in FIG. 132, for convenience of explanation, only two control signal lines (thick line arrows) are shown between the driver IC 741 and the left reel 3L, but in reality, the A phase, A bar phase, and B Since the phase and B-bar phase excitation signals are input to the left reel 3L in parallel, four control signal lines are provided between the driver IC 741 and the left reel 3L.

The "PO3" terminal and "PO4" (output terminal) of the second HB-LSI612, which are connected to the built-in PIO circuit 705 in the second HB-LSI612, are connected to the driver IC 742 for driving the middle reel 3C via the control signal line. The driver IC 742 is connected to the middle reel 3C (second reel) via a control signal line. That is, the PIO circuit 705 built into the second HB-LSI 612 is connected to the middle reel 3C via the driver IC 742.

Between the PIO circuit 705 built into the second HB-LSI 612 and the driver IC 742 for driving the middle reel 3C, data is output in one direction from the "PO3" and "PO4" terminals of the second HB-LSI 612 to the driver IC 742. Between the driver IC 742 and the middle reel 3C, data is output in one direction from the driver IC 742 to the middle reel 3C.

The data (signal) output from the PIO circuit 705 of the second HB-LSI 612 to the driver IC 742 via the "PO3" terminal is an A-phase excitation signal for driving the stepping motor 51C of the middle reel 3C. The data (signal) output to the driver IC 742 via the `` terminal is a B-phase excitation signal for driving the stepping motor 51C of the middle reel 3C. The driver IC 742 for driving the middle reel 3C generates an A-bar phase (inverted phase) excitation signal from the input A-phase excitation signal, and sends the A-phase excitation signal and the A-bar phase excitation signal to the middle reel 3C. Output. In addition, the driver IC 742 for driving the middle reel 3C generates a B-bar phase (inverted phase) excitation signal from the input B-phase excitation signal, and sends the B-phase excitation signal and B-bar phase excitation signal to the middle reel 3C. Output to 3C. In addition, in FIG. 132, for convenience of explanation, only two control signal lines (thick line arrows) are shown between the driver IC 742 and the middle reel 3C, but in reality, the A phase, A bar phase, and B Since the phase and B-bar phase excitation signals are input to the middle reel 3C in parallel, four control signal lines are provided between the driver IC 742 and the middle reel 3C.

The "PO5" terminal and "PO6" (output terminal) of the second HB-LSI612, which are connected to the built-in PIO circuit 705 in the second HB-LSI612, are connected to the driver IC 743 for driving the right reel 3R via the control signal line. The driver IC 743 is connected to the right reel 3R (third reel) via a control signal line. That is, the PIO circuit 705 built into the second HB-LSI 612 is connected to the right reel 3R via the driver IC 743.

Between the PIO circuit 705 built in the second HB-LSI 612 and the driver IC 743 for driving the right reel 3R, data is output in one direction from the "PO5" and "PO6" terminals of the second HB-LSI 612 to the driver IC 743. Between the driver IC 743 and the right reel 3R, data is output in one direction from the driver IC 743 to the right reel 3R.

The data (signal) output from the PIO circuit 705 of the second HB-LSI 612 to the driver IC 743 via the "PO5" terminal is an A-phase excitation signal for driving the stepping motor 51R of the right reel 3R. The data (signal) output to the driver IC 743 via the `` terminal is a B-phase excitation signal for driving the stepping motor 51R of the right reel 3R. The driver IC 743 for driving the right reel 3R generates an A-bar phase (inverted phase) excitation signal from the input A-phase excitation signal, and sends the A-phase excitation signal and A-bar phase excitation signal to the right reel 3R. Output. In addition, the driver IC 743 for driving the right reel 3R generates a B-bar phase (inverted phase) excitation signal from the input B-phase excitation signal, and sends the B-phase excitation signal and B-bar phase excitation signal to the right reel 3R. Output to 3R. In addition, in FIG. 132, for convenience of explanation, only two control signal lines (thick line arrows) are shown between the driver IC 743 and the right reel 3R, but in reality, the A phase, A bar phase, and B Since the phase and B-bar phase excitation signals are input to the right reel 3R in parallel, four control signal lines are provided between the driver IC 743 and the right reel 3R.

In the third gaming machine, the stepping motors 51L, 51C, and 51R that drive the reels are composed of two-phase excitation type stepping motors or one- and two-phase excitation type stepping motors. When two-phase excitation type stepping motors are employed as the stepping motors 51L, 51C, and 51R, gears are provided on the shafts of the reels, and motor power is transmitted through the gears to rotate and stop the reels. Further, when one- and two-phase excitation type stepping motors are adopted as the stepping motors 51L, 51C, and 51R, the motors are connected directly to the shafts of the reels to rotate and stop the reels.

(“PI0” to “PI2” terminals of the second HB-LSI)
The "PI0" terminal (input terminal) of the second HB-LSI 612, which is connected to the PIO circuit 705 built into the second HB-LSI 612, is connected to the index sensor (not shown) of the left reel 3L via a control signal line. . Between the PIO circuit 705 built into the second HB-LSI 612 and the left reel 3L, data is output in one direction from the index sensor of the left reel 3L to the "PI0" terminal of the second HB-LSI 612. Specifically, the detection signal (on/off signal) of the index sensor of the left reel 3L is input to the “PI0” terminal of the second HB-LSI 612.

The "PI1" terminal (input terminal) of the second HB-LSI 612, which is connected to the PIO circuit 705 built into the second HB-LSI 612, is connected to the index sensor (not shown) of the middle reel 3C via a control signal line. . Between the PIO circuit 705 built into the second HB-LSI 612 and the middle reel 3C, data is output in one direction from the index sensor of the middle reel 3C to the "PI1" terminal of the second HB-LSI 612. Specifically, the detection signal (on/off signal) of the index sensor of the middle reel 3C is input to the “PI1” terminal of the second HB-LSI 612.

The "PI2" terminal (input terminal) of the second HB-LSI 612, which is connected to the PIO circuit 705 built into the second HB-LSI 612, is connected to the index sensor (not shown) of the right reel 3R via a control signal line. . Between the PIO circuit 705 built into the second HB-LSI 612 and the right reel 3R, data is output in one direction from the index sensor of the right reel 3R to the "PI2" terminal of the second HB-LSI 612. Specifically, the detection signal (on/off signal) of the index sensor of the right reel 3R is input to the “PI2” terminal of the second HB-LSI 612.

Note that the detection piece (not shown) of the index sensor provided on each reel is arranged on the inner peripheral portion of the reel. There are two types of detection pieces for index sensors: a piece type and a plate type. In the single type, a small detection piece (width: 5 mm to 10 mm) is formed on the inner circumference of the reel, and the detection signal of the index sensor is turned on only when the detection piece is detected. On the other hand, in the plate type, a substantially fan-shaped detection piece is formed on the inner circumference of the reel. In this case, in the section in which the reel makes one revolution, the detection signal of the index sensor is turned on in the section where the detection piece is formed (section within the range of 90° to 180°), and the detection signal of the index sensor is in the on state, and the remaining section ( 360°-(section where the detection piece is formed)), the detection signal of the index sensor is turned off.

(“S0” to “S2” terminals of 2nd HB-LSI)
The “S0” terminal (main/sub switching terminal) of the second HB-LSI 612, which is connected to the PIO circuit 705 built into the second HB-LSI 612, is connected to the 5V power supply (set to on). is set as the main setting. The "S1" and "S2" terminals of the second HB-LSI 612 connected to the built-in PIO circuit 705 of the second HB-LSI 612 are grounded (connected to GND) (set to OFF), so that the second HB-LSI 612 address settings (slave settings) are performed.

[11-6. Configuration of door relay board]
Next, the internal configuration of the door relay board 603 will be explained. FIG. 133 is a diagram showing the internal configuration of the door relay board 603 and the connection relationship between the door relay board 603 and external boards and peripheral devices.

The door relay board 603 has a third HB-LSI 613, as shown in FIG. Note that the configuration of the third HB-LSI 613 is the same as that of the HB-LSI 700 described with reference to FIG. 127, so a description of the configuration will be omitted here.

Furthermore, the door relay board 603 is provided with an optical communication input connector F and an optical communication output connector G that enable connection to an external board using an optical fiber cable. The optical communication input connector F is a photoelectric conversion connector that converts an optical signal into an electrical signal and outputs it, and the optical communication output connector G is an electrical-optical conversion connector that converts an electrical signal into an optical signal and outputs it. be.

(“OP_I” and “OP_O” terminals of 3rd HB-LSI)
The “OP_I” terminal (reception terminal) of the third HB-LSI 613 connected to the built-in serial bus communication circuit 701 of the third HB-LSI 613 is connected to the optical communication input connector F of the door relay board 603 via a control signal line. The optical communication input connector F is connected to the optical communication output connector E of the drum device board 602 via an optical fiber cable. That is, the serial bus communication circuit 701 built into the third HB-LSI 613 is connected to the drum device board 602 via the optical communication input connector F of the third HB-LSI 613 and the optical fiber cable. Then, between the door relay board 603 and the drum device board 602, transmission data (described later) is transmitted from the drum device board 602 to the "OP_I" terminal of the third HB-LSI 613 in the door relay board 603 by synchronous serial communication. (see FIG. 144) is transmitted in one direction.

The “OP_O” terminal (transmission terminal) of the third HB-LSI 613 connected to the built-in serial bus communication circuit 701 of the third HB-LSI 613 is connected to the optical communication output connector G of the door relay board 603 via a control signal line. The optical communication output connector G is connected to the optical communication input connector B of the main control board 601 via an optical fiber cable. That is, the serial bus communication circuit 701 built into the third HB-LSI 613 is connected to the main control board 601 via the optical communication output connector G and the optical fiber cable. Then, between the door relay board 603 and the main control board 601, transmission data (described later in FIG. ) is sent in one direction.

(“POa” to “POg” terminals of 3rd HB-LSI)
“POa” to “POg” terminals (output terminals) of the third HB-LSI 613 connected to the LED drive circuit 703 built into the third HB-LSI 613 are connected to the information display device 14 via a control signal line. Note that seven control signal lines are actually connected in parallel between the "POa" to "POg" terminals of the third HB-LSI 613 and the information display device 14, but in FIG. The main control signal line is indicated by a single thick arrow.

The data (signals) output from the "POa" to "POg" terminals of the third HB-LSI 613 connected to the built-in LED drive circuit 703 in the third HB-LSI 613 configure each 7-segment LED in the information display device 14. This is a 7-segment control signal for controlling lighting/extinguishing (on/off) of seven segments a to g (see FIG. 125B). Specifically, a 7-segment control signal is output from the "POa" to "POg" terminals of the third HB-LSI 613 to the cathodes of each of the seven segments a to g of the seven-segment LED.

Furthermore, the data (signals) output from the "POa" to "POg" terminals of the third HB-LSI 613 are used to turn on/off (on/off) each status display lamp (see FIGS. 125A and 126) in the information display device 14. This is an LED control signal for controlling the LED (off). In each status display lamp in the information display device 14, the "POa" terminal is connected to the cathode of the "INSERT" lamp, the "POb" terminal is connected to the cathode of the "START" lamp, and the cathode of the "REPLAY" lamp is connected to the "POa" terminal. The “POc” terminal is connected to the “1BET” lamp cathode, the “POd” terminal is connected to the “1BET” lamp cathode, the “POe” terminal is connected to the “2BET” lamp cathode, and the “POf” terminal is connected to the “3BET” lamp cathode. (see FIG. 125A) are connected.

(“AS0” to “AS15” terminals of 3rd HB-LSI)
“AS0” to “AS15” terminals (output terminals) of the third HB-LSI 613, which are connected to the LED drive circuit 703 built into the third HB-LSI 613, are connected to the information display device 14 via a control signal line. Note that 16 control signal lines are actually connected in parallel between the "AS0" to "AS15" terminals of the third HB-LSI 613 and the information display device 14, but in FIG. The main control signal line is indicated by a single thick arrow.

The data (signals) output from the "AS0" to "AS15" terminals of the third HB-LSI 613 connected to the built-in LED drive circuit 703 of the third HB-LSI 613 are mainly output from the terminals provided in the information display device 14. This is a control signal for anode selection for dynamically controlling various 7-segment LEDs. Furthermore, the output mode of the data (signals) output from the "AS0" to "AS15" terminals of the third HB-LSI 613 depends on the type of gaming machine (whether it is a normal gaming machine or a medalless gaming machine). It's different. The output modes of the control signals output from the "AS0" to "AS15" terminals are as follows.

First, a case where the gaming machine is a normal gaming machine will be explained. In this case, the control signal for anode selection output from the "AS0" terminal is the second digit (tens' digit) of the credit display lamp (two-digit 7-segment LED: see FIG. 125A) in the information display device 14. It is output to the anode of the 7 segment LED. The control signal for anode selection output from the "AS1" terminal is output to the anode of the 7-segment LED in the first digit (1's digit) of the credit display lamp in the information display device 14.

When the gaming machine is a normal gaming machine, the control signal for anode selection output from the "AS2" terminal is the 2nd one of the payout display lamps (2-digit 7-segment LED: see FIG. 125A) in the information display device 14. It is output to the anode of the 7-segment LED in the digit (tens place). The control signal for anode selection outputted from the "AS3" terminal is outputted to the anode of the 7-segment LED in the first digit (1's digit) of the payout display lamp in the information display device 14.

When the gaming machine is a normal gaming machine, the control signal for anode selection output from the "AS4" terminal is the 3-digit 7-segment LED in the information display device 14 (3-digit 7-segment LED: see FIG. 125A). It is output to the anode of the 7-segment LED of the eye (left side in FIG. 125A). The control signal for anode selection outputted from the "AS5" terminal is outputted to the anode of the 7-segment LED at the second digit (center in FIG. 125A) of the instruction monitor in the information display device 14. The control signal for anode selection outputted from the "AS6" terminal is outputted to the anode of the 7-segment LED at the first digit (on the right side in FIG. 125A) of the instruction monitor in the information display device 14.

Note that the "AS4" to "AS6" terminals are used in the same way when the gaming machine is a medalless gaming machine, and the anode selection is sent from the "AS4" to "AS6" terminals to the instruction monitor 14b (see FIG. 126). control signals are output. That is, the "AS4" to "AS6" terminals are used in both the normal gaming machine and the medalless gaming machine as instruction monitors.

In addition, when the gaming machine is a normal gaming machine, the control signal output from the "AS7" terminal is controlled by each status display lamp ("INSERT", "START", "REPLAY", "1BET") in the information display device 14. ", "2BET", "3BET" lamps (see FIG. 125A). If the gaming machine is a normal gaming machine, the "AS8" to "AS15" terminals are unused.

The "AS7" terminal is also used when the gaming machine is a medalless gaming machine, and each status display lamp ("START", "REPLAY", "1BET", A control signal is output to the anodes of the "2BET" and "3BET" lamps (see FIG. 126). That is, the "AS7" terminal is used for both the normal gaming machine and the medalless gaming machine's status display lamp.

Next, a case where the gaming machine is a medalless gaming machine will be explained. In this case, the control signal for anode selection output from the "AS8" terminal is the first digit (1 digit: output to the anode of the 7-segment LED (7-segment LED located on the rightmost side in FIG. 126). The control signal for anode selection outputted from the "AS9" terminal is outputted to the anode of the 2nd digit (10's digit) 7segment LED of the 5 digits 7segment LED in the information display device 14. The control signal for anode selection outputted from the "AS10" terminal is outputted to the anode of the 3rd digit (100's digit) 7segment LED of the 5 digits 7segment LED in the information display device 14. The control signal for anode selection outputted from the "AS11" terminal is outputted to the anode of the 4th digit (1000's) 7segment LED of the 5 digits 7segment LED in the information display device 14. In addition, the control signal for anode selection output from the "AS12" terminal is the 5th digit (10000 digit: located on the leftmost side in FIG. 126) of the 5-digit 7-segment LED in the information display device 14. 7-segment LED) is output to the anode of the 7-segment LED.

Further, when the gaming machine is a medalless gaming machine, as described above, the control signal for selecting the anode of the 3-digit 7-segment LED (see FIG. 126) of the instruction monitor 14b in the information display device 14 is "AS4". The control signal for each status display lamp (“START”, “REPLAY”, “1BET”, “2BET”, “3BET” lamp: see FIG. 126) in the information display device 14 is output from the terminal ~ “AS6” terminal. , is output from the "AS7" terminal.

If the gaming machine is a medalless gaming machine, the "AS0" to "AS3" terminals and the "AS13" to "AS15" terminals are unused. In addition, if the gaming machine is a medalless gaming machine, a control signal is output from the "AS13" terminal to each status display lamp ("START", "REPLAY", "1BET", "2BET", "3BET" lamp). In this case, the "AS7" terminal will be unused.

(“PO0”, “PI0” to “PI7” terminals of 3rd HB-LSI)
The "PO0" terminal (output terminal) and "PI0" terminal (input terminal) of the third HB-LSI 613, which are connected to the built-in PIO circuit 705 in the third HB-LSI 613, are connected to the medal sensor 31S (medal selector). Data is input and output bidirectionally between the third HB-LSI 613 in the door relay board 603 and the medal sensor 31S (medal selector).

The signal output from the "PO0" terminal of the third HB-LSI 613 to the medal sensor 31S is a control signal of a solenoid provided in the medal selector for controlling on/off the medal pressure that allows or disallows the acceptance of medals. It is. On the other hand, the signal input from the medal sensor 31S (medal selector) to the "PI0" terminal of the third HB-LSI 613 is the signal detected by the medal sensor 31S.

Each input terminal of the 3rd HB-LSI 613, which is connected to the PIO circuit 705 built in the 3rd HB-LSI 613, ``PI1'' terminal, ``PI2'' terminal, and ``PI3'' terminal, is connected to the stop switch 8S ( connected to the stop switch board). Between the third HB-LSI 613 in the door relay board 603 and the stop switch 8S (stop switch board), data is output in one direction from the stop switch 8S to the third HB-LSI 613. Specifically, the signal detected by the stop switch 8S corresponding to the stop button 8L is input to the "PI1" terminal of the third HB-LSI 613, and the signal detected by the stop switch 8S corresponding to the stop button 8C is input to the "PI2" terminal of the third HB-LSI 613. The signal detected by the stop switch 8S corresponding to the stop button 8R is input to the "PI3" terminal of the third HB-LSI 613.

The "PI4" terminal (input terminal) of the third HB-LSI 613, which is connected to the PIO circuit 705 built into the third HB-LSI 613, is connected to the payment switch 9S (payment button 9) via a control signal line. Between the third HB-LSI 613 in the door relay board 603 and the payment switch 9S (payment button 9), data is output in one direction from the payment switch 9S to the third HB-LSI 613. Specifically, the signal detected by the payment switch 9S is input to the "PI4" terminal of the third HB-LSI 613.

The "PI5" terminal (input terminal) of the third HB-LSI 613, which is connected to the PIO circuit 705 built into the third HB-LSI 613, is connected to the start switch 7S (start lever 7) via a control signal line. Between the third HB-LSI 613 in the door relay board 603 and the start switch 7S (start lever 7), data is output in one direction from the start switch 7S to the third HB-LSI 613. Specifically, the signal detected by the start switch 7S is input to the "PI5" terminal of the third HB-LSI 613.

The “PI6” terminal (input terminal) of the third HB-LSI 613, which is connected to the PIO circuit 705 built into the third HB-LSI 613, is connected to the error release switch 57 via a control signal line. Between the third HB-LSI 613 in the door relay board 603 and the error release switch 57, data is output in one direction from the error release switch 57 to the third HB-LSI 613. Specifically, the signal detected by the error release switch 57 is input to the "PI6" terminal of the third HB-LSI 613.

Note that the error release switch 57 is not a switch for canceling an error that is actually occurring and detected by the main CPU, but is used by store personnel or the like to detect the cause of the error (such as medals jammed in the gaming machine, hopper device 32, etc.). When the main CPU detects that the error release switch 57 is pressed (on state), it sets an error flag (not shown) in the main RAM. Clear and return to processing before error detection. Therefore, if the error cancellation switch 57 is pressed (turned on) without eliminating the cause of the error that is occurring, the error will be temporarily canceled, but the error will be immediately detected by the main CPU.

The "PI7" terminal (input terminal) of the third HB-LSI 613, which is connected to the PIO circuit 705 built into the third HB-LSI 613, is connected to the door opening/closing monitoring switch 56 via a control signal line. Between the third HB-LSI 613 in the door relay board 603 and the door opening/closing monitoring switch 56, data is output in one direction from the door opening/closing monitoring switch 56 to the third HB-LSI 613. Specifically, the signal detected by the door opening/closing monitoring switch 56 is input to the "PI7" terminal of the third HB-LSI 613.

(“S0” to “S2” terminals of 3rd HB-LSI)
The "S0" terminal (main/sub switching terminal) of the 3rd HB-LSI 613, which is connected to the PIO circuit 705 built into the 3rd HB-LSI 613, is connected to the 5V power supply (set to ON). is set as the main setting. The "S1" terminal of the third HB-LSI 613, which is connected to the PIO circuit 705 built into the third HB-LSI 613, is connected to a 5V power supply (set to on), and the "S2" terminal is grounded (set to off). As a result, the address setting (slave setting) of the third HB-LSI 613 is performed.

[11-7. Configuration of sub-control unit]
Next, the internal configuration of the sub-control unit 620 will be explained. FIG. 134 is a diagram showing the internal configuration of the sub-control unit 620 and the connection relationship between the sub-control unit 620 and external boards and peripheral devices.

The sub-control unit 620 includes a sub-relay board 621, a sub-control board 622, and a VDP (Video Display Processor) board 623, as shown in FIG. BtoB connections are made between the sub relay board 621 and the sub control board 622, and between the sub control board 622 and the VDP board 623, respectively. Note that the sub-control board 622 and the VDP board 623 are housed in the same case. Although not shown in FIG. 134, a sub ROM (not shown) in which a control program executed by the sub CPU 615 is stored is connected BtoB to the sub relay board 621.

The sub-relay board 621 has a fourth HB-LSI 614. Note that the configuration of the fourth HB-LSI 614 is the same as that of the HB-LSI 700 described in FIG. 127, so a description of the configuration will be omitted here. Further, the sub-relay board 621 is provided with an optical communication input connector H that allows connection to the main control board 601 using an optical fiber cable. Note that the optical communication input connector H is a photoelectric conversion connector that converts an optical signal into an electrical signal and outputs the electrical signal.

The sub control board 622 includes a sub CPU 615 that controls various production operations according to command data transmitted from the main control unit 600 (main control board 601), and a sub CPU 615 that is used as a work area in production control executed by the sub CPU 615. RAM (not shown). Although not shown in FIG. 134, the sub CPU 615 includes a plurality of asynchronous serial communication circuits (UART).

Further, the VDP board 623 (image control board) includes a VDP 616. The VDP 616 is connected to the main display device 210 and the sub display device 220 (with a touch panel) via an LVDS (Low Voltage Differential Signaling) conversion board (not shown) connected BtoB to the VDP board 623. Between the VDP 616 and the main display device 210 and sub display device 220, data is output in one direction from the VDP 616 to the main display device 210 and the sub display device 220. Specifically, the VDP 616 creates image data according to the presentation content on the main display device 210 and/or the sub display device 220, and outputs the created image data to the main display device 210 and/or the sub display device 220. and display it.

(“O_RX” and “O_TX” terminals of the 4th HB-LSI)
The “O_RX” terminal (reception terminal) of the 4th HB-LSI 614, which is connected to the asynchronous serial communication circuit 702 built into the 4th HB-LSI 614, is connected to the optical communication input connector H of the sub-relay board 621 via a control signal line. The optical communication input connector H is connected to the optical communication output connector C of the main control board 601 via an optical fiber cable. That is, the serial bus communication circuit 701 built into the fourth HB-LSI 614 is connected to the main control board 601 via the optical communication input connector H of the fourth HB-LSI 614 and the optical fiber cable. Then, between the sub relay board 621 and the main control board 601, command data (described later in FIG. 137 ) is sent in one direction.

The “O_TX” terminal (transmission terminal) of the 4th HB-LSI 614 connected to the asynchronous serial communication circuit 702 built in the 4th HB-LSI 614 is connected to the built-in sub CPU 615 (sub control board 622) via the control signal line. It is connected to the "UART_R0" terminal (reception terminal) of the sub CPU 615, which is connected to a predetermined asynchronous serial communication circuit. Between the 4th HB-LSI 614 and the sub CPU 615, command data (described later) received by the asynchronous serial communication circuit 702 built into the 4 HB-LSI 614 (see FIG. The data is sent to the "UART_R0" terminal of the PC in one direction by asynchronous serial communication. Specifically, the 4th HB-LSI 614 first reads the transmission data from the main control board 601 via the "O_RX" terminal of the 4th HB-LSI 614, and then converts the gaming control data included in the transmission data into the reception data. By sequentially writing the game control data written in the buffer 721 (see FIG. 128) and then sequentially writing the gaming control data written in the reception data buffer 721 to the transmission data buffer 718 (see FIG. 128), Transmission data from the main control board 601 can be sent to the "UART_R0" terminal of the sub CPU 615.

That is, in the third gaming machine, command data, which will be described later, is transmitted from the main control board 601 via the optical fiber cable to the 4th HB-LSI 614 of the sub-relay board 621, and is sent to the optical communication input connector H of the 4th HB-LSI 614. The photoelectrically converted command data is received by the sub CPU 615 via the asynchronous serial communication circuit 702 built into the fourth HB-LSI 614.

Note that the present invention is not limited to this, and the sub CPU 615 transmits command data from the main control board 601 to the fourth HB-LSI 614 and the sub CPU 615 via a local bus (bus 624, etc.) that connects the fourth HB-LSI 614 and the sub CPU 615. It may also be configured to be acquired from the LSI 614. In this case, there is no need to connect the "O_TX" terminal of the fourth HB-LSI 614 to the "UART_R0" terminal of the sub CPU 615. Alternatively, the optical communication input connector H of the sub-relay board 621 may be directly connected to the "UART_R0" terminal of the sub-CPU 615 via a control signal line. In this case, there is no need to connect the optical communication input connector H and the "O_RX" terminal of the fourth HB-LSI 614 with a control signal line, and the "O_TX" terminal of the fourth HB-LSI 614 is connected to the sub CPU 615 with a control signal line. There is no need to connect it to the "UART_R0" terminal of.

(“PI0” to “PI6” terminals of the 4th HB-LSI)
The "PI0" terminal (input terminal) of the 4th HB-LSI 614, which is connected to the PIO circuit 705 built into the 4th HB-LSI 614, is connected to a PUSH button 631 that is operated by the player according to the content of the performance via the control signal line. (The effect button 10b in FIG. 3). Between the fourth HB-LSI 614 in the sub-relay board 621 and the PUSH button 631, data is output in one direction from the PUSH button 631 to the fourth HB-LSI 614. Specifically, a signal related to the player's operation performed on the PUSH button 631 is input to the “PI0” terminal of the fourth HB-LSI 614.

The "PI1" terminal (input terminal) of the 4th HB-LSI 614 connected to the built-in PIO circuit 705 of the 4th HB-LSI 614 is connected to a chance button 632 which is operated by the player according to the performance content via the control signal line. (The effect button 10a in FIG. 3) is connected. Between the fourth HB-LSI 614 in the sub-relay board 621 and the chance button 632, data is output in one direction from the chance button 632 to the fourth HB-LSI 614. Specifically, a signal related to the player's operation performed on the chance button 632 is input to the “PI1” terminal of the fourth HB-LSI 614.

The "PI2" to "PI6" terminals (input terminals) of the 4th HB-LSI 614, which are connected to the PIO circuit 705 built into the 4th HB-LSI 614, can be operated by the player according to the content of the performance via the control signal line. Various operation switches 633 (for example, cross keys (“↑”, “↓”, “→”, “←”), enter key, etc. are provided corresponding to various operation means other than the PUSH button 631 and the chance button 632. ). Between the fourth HB-LSI 614 in the sub-relay board 621 and the various operation switches 633, data is output in one direction from the various operation switches 633 to the fourth HB-LSI 614. Specifically, signals related to operations performed by the player on various operation means other than the PUSH button 631 and the chance button 632 are input to the "PI2" to "PI6" terminals of the fourth HB-LSI 614.

(“S0” to “S2” terminals of 4th HB-LSI)
The "S0" terminal (main/sub switching terminal) of the 4th HB-LSI 614 connected to the PIO circuit 705 built into the 4th HB-LSI 614 is grounded (set to OFF), and thereby the 4th HB-LSI 614 is set to the sub setting. be done. Also, if the "S1" and "S2" terminals of the 4th HB-LSI 614 are set to an open collector state, noise may enter, so in the third gaming machine, the "S1" and "S2" terminals are Grounded.

(Connection form between sub CPU and external device)
The sub CPU 615 in the sub control board 622 is connected to the fourth HB-LSI 614 in the sub relay board 621 via a bus 624 (including a data bus, address bus, etc.). Specifically, an external bus I/F (not shown) built into the sub CPU 615 and an external bus I/F 707 built into the fourth HB-LSI 614 are connected via a bus 624 (local bus). Data is bidirectionally input and output between the fourth HB-LSI 614 and the sub CPU 615 via the bus 624. For example, various signals input to the “PI0” to “PI6” terminals of the fourth HB-LSI 614 are input to the sub CPU 615 via the bus 624. Therefore, the sub CPU 615 can use the fourth HB-LSI 614 not only as a communication circuit but also as an external connection circuit (IC).

Although not shown in FIG. 134, a sub ROM (not shown) connected BtoB to the sub relay board 621 is connected to the sub CPU 615 not by a local bus but by mSATA (mini Serial ATA). In addition, in the third gaming machine, a configuration example in which the sub ROM is arranged on the sub relay board 621 will be explained, but the present invention is not limited to this, and the sub ROM may be directly connected to the sub control board 622 using mSATA. good.

In addition, although not shown in FIG. 134, a terminal is mounted on the "PO" terminal (output terminal) of the 4th HB-LSI 614 connected to the PIO circuit 705 built in the 4th HB-LSI 614 in order to drive the movable accessory. By connecting a motor, solenoid, etc. via the driver IC, the sub CPU 615 can control the operation of the movable accessory (performance by the movable accessory) via the fourth HB-LSI 614.

The sub CPU 615 is connected to the VDP 616 in the VDP board 623 by a PCI Express 625, and data can be input and output bidirectionally between the sub CPU 615 and the VDP 616 via the PCI Express 625.

The “UART_T1” terminal (transmission terminal) and the “UART_R1” terminal (reception terminal) of the sub CPU 615 connected to the touch panel asynchronous serial communication circuit built into the sub CPU 615 are connected to the touch panel provided in the sub display device 220. connected to. Data is exchanged bidirectionally between the sub CPU 615 and the touch panel of the sub display device 220 by asynchronous serial communication, and the player's operation information on the touch panel is transmitted to the sub CPU 615, and the sub CPU 615 transmits setting information, etc. to the touch panel. Send.

Note that when the main display device 210 is a projector, an asynchronous serial communication circuit different from the asynchronous serial communication circuit for the touch panel built in the sub CPU 615 is connected to the main display device 210 to perform bidirectional communication between the two. I do. In this case, the sub CPU 615 transmits the projector control command to the main display device 210, and the main display device 210 transmits reply information to the transmitted projector control command to the sub CPU 615.

In addition, when the main display device 210 is a projector, a separate relay is provided between the asynchronous serial communication circuit for the touch panel built in the sub CPU 615 and the main display device 210 (projector) and the sub display device 220 (touch panel). A configuration may also be adopted in which a substrate is provided and one asynchronous serial communication circuit within the sub CPU 615 is used to perform bidirectional communication between the sub CPU 615 and the main display device 210 and the sub display device 220. Specifically, the relay board is configured to switch between a mode in which one asynchronous serial communication circuit in the sub CPU 615 and the projector are connected and a mode in which one asynchronous serial communication circuit and the touch panel are connected. It's okay.

[11-8. Data transmission mode between main and sub]
Next, the transmission mode of data (command data) transmitted between the main control unit 600 and the sub-control unit 620, the structure of the command data, etc. will be explained.

[11-8-1. Data transmission cycle between main and sub]
FIG. 135 is a diagram showing a command data transmission mode (time chart) performed between the main control section 600 and the sub-control section 620 of the third gaming machine.

FIG. 135 shows an example in which command data is transmitted in the order of a start command, a reel rotation start command, a no-operation command, a no-operation command, . . . by asynchronous serial communication. Note that the periods labeled "start," "rotation start," and "no operation" in FIG. 135 are transmission periods for the start command, rotation start command, and no operation command, respectively. Further, “Data=**” written above the transmission period of each command data in FIG. 135 indicates the data length (number of bytes) of the game control data group included in the command data. For example, the description "Data=6" in the start command indicates that the data length of the game control data group is 6 bytes, that is, the start command includes 6 game control data (communication parameters). Furthermore, in the description in FIG. 135, the period from the end of command transmission to the start of the next command transmission is described as "sub processing time," but this is because the sub-control unit 620 receives the command. This is the time when processing can be performed after the command is completed, and is not the time for the production control processing itself corresponding to the command.

In the third gaming machine, as shown in FIG. 135, the interval (transmission cycle) from the start of transmission of command data from the main control unit 600 to the sub-control unit 620 to the start of transmission of the next command data is approximately 8 ms. be. Note that the command data transmission cycle is not limited to this example, and can be set as appropriate depending on, for example, the specifications of the gaming machine, the performance of the control system, etc. However, in the third gaming machine, as described later, the data length of the command data transmitted from the main control unit 600 to the sub-control unit 620 can be made variable, so the transmission cycle of the command data is Even if the size of the game control data group (1 packet) included in the data is maximized (32 bytes), it is set to a value that can sufficiently secure the "sub processing time" in FIG. 135.

Note that the manner in which command data is transmitted between the main control section 600 and the sub-control section 620 in the third gaming machine is not limited to the example shown in FIG. 135. For example, a configuration may be adopted in which the interval from the end of transmission of command data to the start of transmission of the next command data is approximately 8 ms. FIG. 136 is a diagram showing a transmission mode (time chart) of command data between the main control unit 600 and the sub-control unit 620 in such an example (modification). Similar to the example shown in FIG. 135, FIG. 136 shows an example in which command data is transmitted in the order of a start command, a reel rotation start command, a no-operation command, a no-operation command, and so on.

In the command data transmission mode shown in FIG. 136, the interval from the end of command data transmission to the start of next command data transmission is constant at approximately 8 ms, but from the start of command data transmission to the next command data transmission start. The interval may change depending on the data length (type of command data) of the command data transmitted first. Note that when the data length of the command data is a fixed length, the interval from the start of transmission of command data to the start of transmission of the next command data is constant also in the example shown in FIG.

[11-8-2. Configuration of transmission data between main and sub]
Next, the structure of data (command data) transmitted from the main control section 600 to the sub-control section 620 by asynchronous serial communication will be explained. FIG. 137 is a diagram showing the structure of command data (asynchronous serial communication data) transmitted from main control section 600 to sub-control section 620 in the third gaming machine.

The command data sent from the main control unit 600 to the sub-control unit 620 includes start data (STX), error detection code data (CRC16), gaming control data group (“d0” to “dn”), and End data (ETX) is arranged and configured in this order. The error detection code data (CRC16) may be placed between the gaming control data group (“d0” to “dn”) and the end data (ETX), or may be placed after the end data (ETX). You may.

The start data (STX) is 1 byte, the error detection code data (CRC16) is 2 bytes, the data length of the game control data group ("d0" to "dn") is 2 bytes to 32 bytes, and the end data is 2 bytes. Data (ETX) is 1 byte. Therefore, in the third gaming machine, the maximum data length of one command data transmitted from the main control unit 600 to the sub-control unit 620 is 36 bytes when the DLE control described below is not performed, and the minimum data length is 36 bytes. is 6 bytes. In addition, if the data length of the game control data group is 32 bytes and the DLE control described below is performed on all 32 bytes of game control data, the maximum data length of the two command data will be 68 bytes. Become.

The gaming control data group (“d0” to “dn”) consisting of a plurality of pieces of gaming control data includes, as gaming control data (communication parameters), information indicating the command type (command ID), gaming status at the time of command transmission, and gaming. Contains various information regarding progress. Various information (communication parameters) regarding the game status and game progress included in the game control data group (“d0” to “dn”) include, for example, information regarding internal winning combinations, RT status (gaming status), ball output status, Examples include navigation data, but the type of information included in the game control data group changes depending on the command type. Therefore, the content and number of information (communication parameters) included in the gaming control data group changes depending on the command type, and the data length of the gaming control data group changes depending on the command type.

[11-8-3. DLE control]
In the third gaming machine, the gaming control data group (“d0” to “dn”) includes gaming control data with the same value as any of DLE data (DLE), start data (STX), and end data (ETX). In this case, the option provision circuit (see FIG. 128) in the first HB-LSI 611 mounted on the main control board 601 performs DLE control (conversion) on the game control data. Subsequent game control data is transmitted to the sub-control unit 620 together with the DLE data. When the sub-control unit 620 side receives the DLE data, the option check circuit (see FIG. 128) in the fourth HB-LSI 614 mounted on the sub-relay board 621 controls the game after the received DLE control (conversion). Restore the data to the original game control data.

FIG. 138 shows the correspondence between gaming control data before DLE conversion, gaming control data (transmission data) after DLE conversion, control equations used during DLE conversion, and control equations used during DLE restoration. It is a table.

In the third gaming machine, as shown in FIG. 138, the start data (STX) and end data (ETX) are set to "7EH" and "7FH", respectively, and the DLE data (DLE) is set to "7DH". It is set. Note that the values of the DLE data, start data, and end data are not limited to the values in this example, but can be set to arbitrary values. Hereinafter, with reference to FIG. 138, the transmission/reception operation of gaming control data to be subject to DLE control (conversion) and the contents of the DLE control performed on the gaming control data at that time will be specifically explained.

(If the game control data is "7DH")
For example, if the game control data to be transmitted is the same data "7DH" as the DLE data (DLE), when transmitting the data, the main control unit 600 side performs an exclusive OR (xor) of "20H" and "7DH". ) is performed, and the calculation result "5DH" becomes the game control data after DLE conversion. In this case, "7DH" (DLE data) and "5DH" (gaming control data after DLE conversion) are transmitted to the sub-control unit 620 in this order.

On the other hand, when the sub-control unit 620 side receives "7DH" (DLE data), the exclusive OR of "5DH" (game control data after DLE conversion) received next and "20H" ( xor) is performed, and the result of the calculation is "7DH", and the original game control data is restored.

(If the game control data is "7EH")
For example, if the game control data to be transmitted is the same data "7EH" as the start data (STX), when transmitting the data, the main control unit 600 side performs an exclusive OR (xor) of "20H" and "7EH". ) is performed, and the calculation result "5EH" becomes the game control data after DLE conversion. In this case, "7DH" (DLE data) and "5EH" (gaming control data after DLE conversion) are transmitted to the sub-control unit 620 in this order.

On the other hand, when the sub-control unit 620 side receives "7DH" (DLE data), the exclusive OR ( xor) is performed, and the result of the calculation is "7EH", and the original gaming control data is restored.

(If the game control data is "7FH")
For example, if the gaming control data to be transmitted is the same data "7FH" as the end data (ETX), when transmitting the data, the main control unit 600 side performs an exclusive OR of "20H" and "7FH". (xor) calculation is performed, and the calculation result "5FH" becomes the game control data after DLE conversion. In this case, "7DH" (DLE data) and "5FH" (gaming control data after DLE conversion) are transmitted to the sub-control unit 620 in this order.

On the other hand, when the sub-control unit 620 side receives "7DH" (DLE data), the exclusive OR ( xor) is performed, and the result of the calculation is "7FH", and the original game control data is restored.

(Example of command data configuration when DLE control is not performed)
FIG. 139 is a diagram showing a configuration example of command data transmitted from main control section 600 to sub-control section 620 when DLE control (conversion) is not performed on game control data.

In the example of command data shown in FIG. 139, there are six pieces of gaming control data to be transmitted, and the gaming control data group (“d0” to “d5”) includes start data (STX), end data (ETX), and Data that is the same as any of the DLE data (DLE) (any of "7DH", "7EH", and "7FH") is not included. Therefore, for such a gaming control data group, DLE control is not performed at the time of data transmission, so the data length of the gaming control data group to be transmitted is 6 bytes, and the data length of command data is 10 bytes. Become a part-time worker.

(Example of command data configuration when DLE control is performed)
FIG. 140 is a diagram for explaining a configuration example of command data transmitted from main control unit 600 to sub-control unit 620 when DLE control (conversion) is performed on game control data. FIG. 140A is a diagram showing a configuration example of a gaming control data group to be transmitted (before DLE conversion), and FIG. 140B is a diagram showing a command after performing DLE control (conversion) on the gaming control data group shown in FIG. 140A. It is a figure showing an example of a data composition. In addition, in the example shown in FIG. 140, similarly to the example shown in FIG. 139, a case will be described in which six pieces of game control data are transmitted.

In this example, as shown in FIG. 140A, the value of the game control data "d3" in the fourth byte from the beginning in the game control data group to be transmitted is "7DH", which is the same as the DLE data (DLE). In this case, before transmitting the gaming control data "d3" written in the transmission data buffer 718, the value "7DH" of the gaming control data "d3" is converted to "5DH" by DLE control (conversion). In this case, after transmitting the DLE data (7DH), the game control data after DLE conversion ("5DH") is transmitted.

As a result, in the command data shown in FIG. 140B, the DLE data ("7DH") and the game control data after DLE conversion ("5DH") are the game control data in the fourth byte from the beginning in the game control data group. The configuration is set in "d3" and the fifth byte of game control data "d4". At this time, the game control data "d4" in the 5th byte and the game control data "d5" in the 6th byte from the beginning of the game control data group before DLE conversion shown in FIG. 140A are also shifted backward by 1 byte. , the 6th byte game control data "d5" and the 7th byte game control data "d6" in the game control data group are respectively set.

Therefore, in the example shown in FIG. 140B, the data length of the gaming control data group in the command data is 1 byte longer than the data length of the gaming control data group before DLE conversion, so the data length of the entire command data is also 1 byte. become longer. In addition, in the command data transmission operation shown in FIG. 140B, when transmitting the 4th byte DLE data ("7DH") and the 5th byte DLE-converted game control data ("5DH"), these data are It is not written to the transmission data buffer 718, but is directly set in the transmission shift register 719 and transmitted after DLE control (conversion).

[11-8-4. Example of storing data sent between main and sub]
Next, a process for generating and storing a gaming control data group included in data (command data) transmitted from the main control unit 600 to the sub-control unit 620 by asynchronous serial communication will be described. Here, in order to simplify the explanation, it is assumed that the gaming control data group of one packet to be transmitted does not include gaming control data that is subject to DLE control. Moreover, the generation and storage process of a game control data group, which will be described below, is executed and controlled by the main CPU of the microprocessor 610 mounted on the main control board 601.

(Example of generation and storage process of game control data group in conventional game machine)
First, before explaining the generation and storage process of a game control data group performed in the third game machine, in order to clarify its characteristics, we will explain the process performed in a conventional game machine (a game machine not equipped with an HB-LSI). The generation and storage process of the game control data group will be explained.

In addition, here, in order to clarify the characteristics of the generation and storage process of the gaming control data group performed in the third gaming machine, the data length of the gaming control data group included in the transmission data transmitted to the sub-control unit 620 will be explained. An example in which the length is set to a fixed length of 7 bytes, that is, an example in which the number of game control data to be transmitted is set to 7 will be explained. Furthermore, here, data indicating the command type (command ID) is set in the game control data placed at the beginning of the game control data group, and data regarding the gaming state is set in the game control data placed at the end. It is assumed that various data related to the game situation and game progress are set in the game control data (communication parameters 1 to 5, which will be described later) placed second to sixth from the beginning.

In addition, in conventional gaming machines (gaming machines without HB-LSI), the main CPU has an accumulator A (hereinafter referred to as "A register"), a general-purpose register B (hereinafter referred to as "B register"), and a general-purpose register B (hereinafter referred to as "B register"). Register C (hereinafter referred to as "C register"), general purpose register D (hereinafter referred to as "D register"), general purpose register E (hereinafter referred to as "E register"), general purpose register H (hereinafter referred to as "H register") ''), general-purpose register L (hereinafter referred to as "L register"), and a communication data storage area provided in the main RAM to generate and store a group of gaming control data. Note that the data length of each register is 1 byte.

FIG. 141 is a flowchart showing the procedure of a game control data group generation/storage process (communication data storage process) executed by the main control section of a conventional gaming machine.

First, the main CPU determines whether there is any free space in the communication data storage area provided in the main RAM (S401). In S401, if the main CPU determines that there is no free space in the communication data storage area (NO determination in S401), the main CPU ends the game control data group generation and storage process (communication data storage process). .

On the other hand, in S401, if the main CPU determines that there is space in the communication data storage area (YES in S401), the main CPU determines that there is a free space in the communication data storage area (YES in S401), the main CPU stores the command ID (gaming control The data "d0") is set (stored) in a communication data temporary area (not shown) of the main RAM (S402).

Next, the main CPU sets (stores) communication parameter 1 (gaming control data "d1") related to the gaming situation set in the B register in a communication data temporary area (not shown) of the main RAM (S403). Next, the main CPU sets communication parameter 2 (gaming control data "d2") related to the gaming situation set in the C register in the communication data temporary area (S404). Next, the main CPU sets communication parameter 3 (gaming control data "d3") related to the gaming situation set in the D register in the communication data temporary area (S405). Next, the main CPU sets communication parameter 4 (gaming control data "d4") related to the gaming situation set in the E register in the communication data temporary area (S406). Next, the main CPU sets communication parameter 5 (gaming control data "d5") related to the gaming situation set in the H register in the communication data temporary area (S407). Next, the main CPU sets data related to the gaming state (gaming control data "d6") set in the L register in the communication data temporary area (S408).

Next, the main CPU sets the data set in the communication data temporary area of the main RAM into a communication data storage area provided in the main RAM (S409). Next, the main CPU generates a sum value (BCC) of the command data to be transmitted using the data set in the A register, B register, C register, D register, E register, H register, and L register, and The sum value is set in the communication data storage area (S410). After the process of S410, the main CPU ends the game control data group generation/storage process (communication data storage process).

(Example 1 of generation and storage processing of game control data group in third gaming machine)
Next, when a third gaming machine generates the same gaming control data group as the gaming control data group generated in the gaming control data group generation/storage process described in FIG. 141, a gaming control data group generation/storage process is performed. Example 1 will be explained. FIG. 142 is a flowchart showing the procedure of the first embodiment of the game control data group generation/storage process (communication data storage process) executed by the main control unit 600 of the third gaming machine. In the first embodiment, the main CPU of the microprocessor 610 mounted on the main control board 601 is the first data set register 711 and the second data set register 712 in the first HB-LSI 611 mounted on the main control board 601. Using the transmission data buffer 718, generation and storage processing of a game control data group is performed.

First, the main CPU determines whether there is space in the transmission data buffer 718 in the first HB-LSI 611 (S411). In this process, the main CPU refers to information stored in the status register T (see FIG. 129A) provided in the status monitoring circuit 714 in the first HB-LSI 611, and determines whether there is free space in the transmission data buffer 718. Determine whether In S411, if the main CPU determines that there is no free space in the transmission data buffer 718 (NO determination in S411), the main CPU ends the game control data group generation/storage process (communication data storage process). .

On the other hand, in S411, if the main CPU determines that there is space in the transmission data buffer 718 (YES in S411), the main CPU sends the command ID (gaming control data "d0") indicating the command type. , is set in the first data set register 711 (S412). Also, through this process, the command ID set in the first data set register 711 is written into the transmission data buffer 718.

Note that in S411, if the main CPU determines that there is space in the transmission data buffer 718, bit 0 (B0) of status register T (see FIG. 129A) is on (“1”), and bit 1 This applies when (B1) is on (“1”) or bit 2 (B2) is on (“1”). Furthermore, in S411, the main CPU determines that there is free space in the transmission data buffer 718 under the conditions that bit 5 (B5) of status register T is on (“1”) and/or bit 6 (B6) is on ( The condition "1") may be added.

Next, the main CPU sets communication parameter 1 (gaming control data "d1") regarding the gaming situation in the first data set register 711 (S413). Also, through this process, communication parameter 1 set in the first data set register 711 is written to the transmission data buffer 718. At this time, in the transmission data buffer 718, communication parameter 1 is written to the address next to the address where the command ID is stored.

Next, the main CPU sets communication parameter 2 (gaming control data "d2") regarding the gaming situation in the first data set register 711 (S414). Also, through this process, communication parameter 2 set in the first data set register 711 is written to the transmission data buffer 718. At this time, within the transmission data buffer 718, communication parameter 2 is written to the address next to the address where communication parameter 1 is stored.

Next, the main CPU sets communication parameter 3 (gaming control data "d3") regarding the gaming situation in the first data set register 711 (S415). Also, through this process, the communication parameter 3 set in the first data set register 711 is written into the transmission data buffer 718. At this time, in the transmission data buffer 718, communication parameter 3 is written to the address next to the address where communication parameter 2 is stored.

Next, the main CPU sets communication parameter 4 (gaming control data "d4") regarding the gaming situation in the first data set register 711 (S416). Also, through this process, the communication parameter 4 set in the first data set register 711 is written into the transmission data buffer 718. At this time, in the transmission data buffer 718, communication parameter 4 is written to the address next to the address where communication parameter 3 is stored.

Next, the main CPU sets communication parameter 5 (gaming control data "d5") related to the gaming situation in the first data set register 711 (S417). Also, through this process, the communication parameter 5 set in the first data set register 711 is written into the transmission data buffer 718. At this time, in the transmission data buffer 718, communication parameter 5 is written to the address next to the address where communication parameter 4 is stored.

Next, the main CPU sets data regarding the gaming state (gaming control data "d6") in the second data set register 712 (S418). Also, through this process, the data related to the gaming state set in the second data set register 712 is written into the transmission data buffer 718. At this time, in the transmission data buffer 718, data related to the gaming state is written to the address next to the address where the communication parameter 5 is stored.

In addition, in the third gaming machine, as described above, the second data set register 712 stores the last gaming control data of the gaming control data group of one packet to be transmitted. Completion of writing of the group is determined. Therefore, the main CPU determines that writing of one packet of game control data group to the transmission data buffer 718 is completed by setting the game control data to the second data set register 712 in the process of S418. . After the process of S418, the main CPU ends the game control data group generation/storage process (communication data storage process).

In addition, in the generation and storage process (communication data storage process) of the game control data group described above, the main CPU sets each game control data in the first data set register 711 or the second data set register 712, and stores the data in the transmission data buffer. 718, it is checked whether bit 4 (B4) of the status register T (see FIG. 129A) is set to on (“1”) (whether there is a transfer error or not), and the status register T If bit 4 (B4) is on, the process of writing game control data to the transmission data buffer 718 may be interrupted.

(Example 2 of generation and storage processing of game control data group in third gaming machine)
In the first embodiment of FIG. 142, the generation and storage process of the game control data group that is applicable when the data length of the game control data group is set to a fixed length has been explained, but in the third gaming machine, as described above, The data length of the game control data group can be made variable. Here, we will explain the process for generating and storing a gaming control data group (Example 2) which is applicable not only when the data length of the gaming control data group is a fixed length but also when the data length of the gaming control data group is variable. ).

FIG. 143 is a flowchart showing the procedure of the second embodiment of the game control data group generation/storage process (communication data storage process) executed by the main control unit 600 of the third gaming machine. Note that in the second embodiment, the main CPU not only controls the first data set register 711, second data set register 712, and transmission data buffer 718 in the first HB-LSI 611 mounted on the main control board 601, but also the main RAM, A game control data group generation and storage process is performed using the A register, B register, and HL pair register (data length is 2 bytes) configured by combining the H register and L register that the main CPU has. In addition, in the second embodiment, various game control data (communication parameters related to gaming conditions) transmitted according to the command type (command ID) are stored in a predetermined area (hereinafter referred to as It is assumed that the data are stored collectively (consecutively in terms of addresses) in the "transmission target storage area"). For example, the transmission target storage area corresponding to the start command transmitted in response to the ON state of the start switch 7S contains, as game control data, the internal winning combination of the main RAM, the type of lock (reel) effect, the type of freeze effect. (freeze time), RT status, and game status are stored together.

First, the main CPU determines whether there is space in the transmission data buffer 718 in the first HB-LSI 611 (S421). In this process, the main CPU refers to information stored in the status register T (see FIG. 129A) provided in the status monitoring circuit 714 in the first HB-LSI 611, and determines whether there is free space in the transmission data buffer 718. Determine whether In S421, if the main CPU determines that there is no free space in the transmission data buffer 718 (NO determination in S421), the main CPU ends the game control data group generation/storage process (communication data storage process). .

On the other hand, in S421, if the main CPU determines that there is space in the transmission data buffer 718 (YES in S421), the main CPU transfers the command ID (gaming control data "d0") to the first data Set in the set register 711 (S422). Also, through this process, the command ID set in the first data set register 711 is written into the transmission data buffer 718.

Next, the main CPU sets the number of remaining gaming control data to be transmitted (hereinafter referred to as the "transmission number") in the B register (S423). In addition, the number of transmissions set in the process of S423 is obtained by subtracting 1 from the number of gaming control data "n" included in the gaming control data group of 1 packet to be transmitted (subtracting the data of the command type (command ID)). value. For example, if the number of game control data included in the game control data group of one packet to be transmitted is "7", "6" is set as the number of transmissions in the B register in the process of S423.

Next, the main CPU sets the address (starting address) of the transmission target storage area in the main RAM corresponding to the command type (command ID) to be processed in the HL pair register (S424).

Next, the main CPU transfers the communication parameters (gaming control data) stored in the address (starting address or updated address) of the transmission target storage area currently set in the HL pair register to the first data set register. 711 (S425). Also, through this process, the communication parameters (gaming control data) set in the first data set register 711 are written into the transmission data buffer 718. At this time, the communication parameters (gaming control data) are the communication parameters written in the transmission data buffer 718 in the previous process of setting communication parameters to the first data set register 711 (S422 or S425). (gaming control data) is written to the next address. Note that after the processing in S425, the main CPU reads the status register T (see FIG. 129A), and if bit 4 (B4) is on (“1”), interrupts the processing and generates and stores the gaming control data group. The process (communication data storage process) may be terminated.

Next, the main CPU adds 1 to the value of the HL pair register (S426). Through this process, the address in the transmission target storage area from which the communication parameters (gaming control data) are to be read is updated. Next, the main CPU subtracts 1 from the value of the B register (S427). Through this process, the number of transmissions (the number of remaining game control data) is updated.

Next, the main CPU determines whether the value of the B register (number of transmissions) is "1" (S428).

In S428, if the main CPU determines that the value of the B register (number of transmissions) is not "1" (NO determination in S428), the main CPU returns the process to S425 and repeats the processes in S425 to S428. repeat.

On the other hand, in S428, if the main CPU determines that the value of the B register (number of transmissions) is "1" (YES in S428), the main CPU determines that the value of the B register (number of transmissions) is "1" (YES in S428), The communication parameter (information regarding the game state: game control data "dn") stored at the last address in the transmission target storage area is set in the second data set register 712 (S429). Also, through this process, the communication parameter (gaming control data “dn”) set in the second data set register 712 is written into the transmission data buffer 718. At this time, the communication parameter (gaming control data "dn") is stored in the transmission data buffer 718 as the communication parameter written in the transmission data buffer 718 in the previous process of setting the communication parameter to the first data set register 711 (S425). It is written to the address next to the address of the parameter (gaming control data "dn-1"). Note that the main CPU determines that writing of one packet of game control data group has been completed by setting it in the second data set register 712 in S429. After the process of S429, the main CPU ends the game control data group generation/storage process (communication data storage process).

In the asynchronous serial communication circuit 702, communication parameters are set in the second data set register 712 in the process of S429, and the set communication parameters are written in the transmission data buffer 718, thereby writing one packet worth of game control data group. is completed. As a result, the data length for one packet is determined, and the determined data length is set in the transmission packet counter of the corresponding packet.

[11-9. Data transmission using synchronous serial communication]
Next, synchronous serial communication of data performed between the main control board 601, the drum unit board 602, and the door relay board 603 within the main control unit 600 will be described.

[11-9-1. Example 1 of data structure transmitted by synchronous serial communication]
(Overall structure of transmission data)
FIG. 144 is a diagram showing a first configuration example of data transmitted by synchronous serial communication between the main control board 601, the drum device board 602, and the door relay board 603. In addition, in FIG. 144, for convenience of explanation, input/output data for peripheral devices set in the transmission data are shown not only by the value of the transmitted data ("value" in the diagram) but also by the name indicating the type of each data. ("Slave 1 (2nd HB-LSI) output data" in the figure, etc.), the storage area (RAM and register ) addresses (such as "FED0H" in the diagram) and ports through which each data is input/output (such as "PO0" in the diagram) are also described.

In addition, in FIG. 144, for convenience of explanation, the display data of the information display device 14 set in the transmission data includes not only the value of the display data ("value" in the diagram: "00H to FFH") but also each display data. A name indicating the type of data (such as "7-segment display data 1-1" in the figure), a storage area for each display data in the master (1st HB-LSI 611) that is the source and final destination of the display data. (RAM or register) address (such as "FED4H" in the figure), as well as the type of 7-segment LED and lamp displayed with each display data (such as "2-digit 7-seg for credit display" in the figure). has been done.

Furthermore, in FIG. 144, for convenience of explanation, in each 1-byte data included in the transmission data, the bits located on the right side in the drawing are the more significant bits. Therefore, for example, in the first byte of data in "slave 1 (second HB-LSI) output data", the leftmost bit (the bit corresponding to output port "PO0") is the least significant bit ( The bit located on the rightmost side (the bit corresponding to output port "PO7") becomes the most significant bit (MSB).

As shown in FIG. 144, the transmission data in configuration example 1 includes, from the beginning, 2-byte data each called "slave 1 (second HB-LSI) output data" to "slave 4 (spare) output data"; 1-byte data each called "7-segment display data 1-1" to "7-segment display data 1-4 (shared use)", 1-byte data called "status display data (shared use)", "7-segment display data 2-1" to "7-segment display data 2-3", each 1 byte of data, and "Slave 1 (2nd HB-LSI) input data" to "Slave 4 (spare) input data" of 2 bytes each. Data and 2-byte data called "CRC16" are arranged in this order. That is, in configuration example 1, the size (data length) of the data portion within one transmission data is 26 bytes. Note that the actual transmission data is configured in a data format according to the communication specifications of the synchronous serial bus communication used, and transmission data in this data format is sent and received between master and slave and between slave and slave. , the description of the communication specifications will be omitted here.

In addition, in the third gaming machine, between the main CPU and the master (first HB-LSI 611), when the main CPU of the microprocessor 610 provided on the main control board 601 writes the data to be output to each slave into the transmission data, , and when reading the data input by each slave from the transmitted data, by specifying the address of the data storage area (RAM or register) in the master as shown in FIG. Data input/output is performed at . The contents of various data set in the transmission data will be explained below.

(Slave 1 (2nd HB-LSI) output data ~ Slave 4 (spare) output data)
The data set in "Slave 1 (2nd HB-LSI) output data" is output (set ). That is, "slave 1 (second HB-LSI) output data" includes data output to peripheral devices such as the hopper device 32 connected to the drum device board 602 (PIO circuit 705), each reel, etc. (see FIG. 132). Data (control signal) is set.

The data set in "Slave 2 (3rd HB-LSI) output data" is output (set) to the "PO0" to "PO15" terminals of the 3rd HB-LSI 613 (PIO circuit 705) mounted on the door relay board 603. This is the data that will be used. That is, "slave 2 (third HB-LSI) output data" includes data that is output to peripheral devices such as the medal sensor 31S and stop switch 8S (see FIG. 133) connected to the door relay board 603 (PIO circuit 705). Data (control signal) is set.

Note that in the third gaming machine, the HB-LSI corresponding to "slave 3" and "slave 4" is not provided, so the 2-byte "slave 3 (spare) output data" and "slave 4 (spare) The "output data" are unused, and any data can be set in these output data. In the third gaming machine, a 2-byte "slave" is included in the transmission data so that it can be applied even when an HB-LSI that is set as a slave is further provided in the main control unit 600 due to function expansion etc. 3 (preliminary) output data" and "slave 4 (preliminary) output data". Therefore, when only two HB-LSIs configured as slaves are provided in the main control unit 600, "slave 3 (spare) output data" and "slave 4 (spare) output data" are included in the transmission data. A configuration may also be adopted in which it is not provided.

Setting processing of "slave 1 (second HB-LSI) output data" to "slave 4 (spare) output data" is performed by the main control board 601 (first HB-LSI 611) when transmitting data.

(7 segment display data 1-1, 7 segment display data 1-2)
Each 1-byte display data set in “7-segment display data 1-1” and “7-segment display data 1-2” is output (set) to the third HB-LSI 613 mounted on the door relay board 603. This is display data used when the gaming machine is a normal gaming machine (non-medalless gaming machine).

The display data set in "7-segment display data 1-1" is display data for controlling the lighting/extinguishment of the credit display lamp (2-digit 7-segment LED: see FIG. 125A) in the information display device 14. That is, the display data set in "7-segment display data 1-1" is for 7-segment LEDs that are controlled to turn on/off by the "AS0" and "AS1" terminals of the third HB-LSI 613 (LED drive circuit 703). This is the display data. Note that if the gaming machine is a medalless gaming machine, the "7 segment display data 1-1" is not used, so any data can be set in the "7 segment display data 1-1".

The display data set in "7-segment display data 1-2" is display data for controlling the lighting/extinguishment of the payout display lamp (2-digit 7-segment LED: see FIG. 125A) in the information display device 14. That is, the display data set in "7-segment display data 1-2" is for 7-segment LEDs that are controlled to turn on/off by the "AS2" and "AS3" terminals of the third HB-LSI 613 (LED drive circuit 703). This is the display data. Note that if the gaming machine is a medalless gaming machine, the "7 segment display data 1-2" is not used, so any data can be set in the "7 segment display data 1-2".

Setting processing of "7-segment display data 1-1" and "7-segment display data 1-2" is performed by the main control board 601 (first HB-LSI 611) when transmitting data.

(7 segment display data 1-3 (shared use), 7 segment display data 1-4 (shared use))
Each 1-byte display data set in “7 segment display data 1-3 (shared use)” and “7 segment display data 1-4 (shared use)” is sent to the third HB-LSI 613 mounted on the door relay board 603. This is data that is output (set), and is display data that is used (combined) regardless of whether the gaming machine is a regular gaming machine or a medalless gaming machine.

The display data set in "7 segment display data 1-3 (common use)" is the 3rd digit (in the figure) of the instruction monitor (3 digit 7 segment LED: Figures 125A and 126) in the information display device 14. This is display data for lighting/extinguishing control of the 7-segment LED on the left (corresponding to the left reel 3L) and the 7-segment LED of the second digit (7-segment LED in the center in the figure: corresponding to the middle reel 3C). In other words, the display data set in "7-segment display data 1-3 (common use)" is the 7-segment display data that is controlled to turn on/off by the "AS4" and "AS5" terminals of the third HB-LSI 613 (LED drive circuit 703). This is display data for Seg LED.

The display data set in "7 segment display data 1-4 (common use)" is the 1st digit (in the figure) of the instruction monitor (3 digit 7 segment LED: Figures 125A and 126) in the information display device 14 7-segment LED on the right side: This is display data for lighting/extinguishing control of the 7-segment LED (corresponding to the right reel 3R). In other words, the display data set in "7-segment display data 1-4 (common use)" is the display for the 7-segment LED that is controlled to turn on/off by the "AS6" terminal of the third HB-LSI 613 (LED drive circuit 703). It is data. In configuration example 1, the display data for the 7-segment LED in the first digit of the instruction monitor is set in the lower 4 bits of "7-segment display data 1-4 (common use)", and the upper 4 bits are Unused (any data can be set).

Setting processing of "7-segment display data 1-3 (common use)" and "7-segment display data 1-4 (common use)" is performed by the main control board 601 (first HB-LSI 611) when transmitting data.

(Status display data (also used))
The 1-byte display data set in the "status display data (common use)" is data that is output (set) to the third HB-LSI 613 mounted on the door relay board 603, and indicates that the gaming machine is a normal gaming machine or This is display data that is used (combined) for any medalless gaming machine. The 1-byte display data set in "Status display data (common use)" is used to display various status display LEDs (various status display lamps in FIGS. 125A and 126) provided in the information display device 14. This is display data for controlling lights out. That is, the display data set in "Status display data (common use)" is display data for a status display lamp whose lighting/extinguishing is controlled by the "AS7" terminal of the third HB-LSI 613 (LED drive circuit 703).

Each bit from the lowest bit to the 6th bit in "Status display data (also used)" has an "INSERT" lamp, "START" lamp, "REPLAY" lamp, "1BET" lamp, and "2BET" lamp respectively. And display data (0 (off)/1 (on) data) for controlling the lighting/extinguishment of the "3BET" lamp is set. Note that the 7th and 8th bits in the "status display data (common use)" are unused, and any data can be set in these bits. Furthermore, if the gaming machine is a medalless gaming machine, the least significant bit in the "status display data (also used)" is unused.

Setting processing of "status display data (common use)" is performed by the main control board 601 (first HB-LSI 611) when transmitting data.

(7 segment display data 2-1 to 7 segment display data 2-3)
Each 1-byte display data set in “7-segment display data 2-1” to “7-segment display data 2-3” is output (set) to the third HB-LSI 613 mounted on the door relay board 603. This is display data used when the gaming machine is a medalless gaming machine. Note that if the gaming machine is not a medalless gaming machine, "7 segment display data 2-1" to "7 segment display data 2-3" are not used, so "7 segment display data 2-1" to "7 segment display data Any data can be set in "2-3".

The display data set in "7-segment display data 2-1" is the first digit (1's digit) of the 5-digit 7-segment LED (see FIG. 126) provided in the status display monitor 14a of the information display device 14. : This is display data for lighting/extinguishing control of the 7-segment LED located on the rightmost side in the figure) and the 7-segment LED in the second digit (tens place). That is, the display data set in "7-segment display data 2-1" is for 7-segment LEDs that are controlled to turn on/off by the "AS8" and "AS9" terminals of the third HB-LSI 613 (LED drive circuit 703). This is the display data.

The display data set in "7 segment display data 2-2" is the 3rd digit (100's digit) of the 5 digit 7 segment LED (see FIG. 126) provided in the status display monitor 14a of the information display device 14. ) and the fourth digit (1000's place) is display data for controlling the lighting/extinguishing of the 7-segment LED. That is, the display data set in "7-segment display data 2-2" is for 7-segment LEDs that are controlled to turn on/off by the "AS10" and "AS11" terminals of the third HB-LSI 613 (LED drive circuit 703). This is the display data.

The display data set in "7 segment display data 2-3" is the 5th digit (10000 digit) of the 5 digit 7 segment LED (see FIG. 126) provided in the status display monitor 14a of the information display device 14. : This is display data for controlling the lighting/extinguishment of the 7-segment LED (the 7-segment LED located on the leftmost side in the figure). That is, the display data set in "7-segment display data 2-3" is display data for a 7-segment LED that is controlled to turn on/off by the "AS12" terminal of the third HB-LSI 613 (LED drive circuit 703). . In addition, in configuration example 1, the display data of the 5th digit 7-segment LED is set in the lower 4 bits of "7-segment display data 2-3", and the display data in the upper 4 bits is unused. (Any data can be set).

Setting processing of "7-segment display data 2-1" to "7-segment display data 2-3" is performed by the main control board 601 (first HB-LSI 611) when transmitting data.

In this embodiment, an example has been described in which the information display device 14 is connected to the third HB-LSI 613 mounted on the door relay board 603, but the present invention is not limited to this. For example, the information display device 14 may be connected to the second HB-LSI 612 mounted on the drum device board 602, and in this case as well, the display processing of the information display device 14 described above is applied as in this embodiment. can do.

(Slave 1 (2nd HB-LSI) input data ~ Slave 4 (spare) input data)
The data set in “Slave 1 (2nd HB-LSI) input data” is input to the “PI0” to “PI15” terminals of the 2nd HB-LSI 612 (PIO circuit 705) mounted on the reel device board 602. It is data. That is, "slave 1 (second HB-LSI) input data" includes data (detection signal ) is set. Note that the setting process for "slave 1 (second HB-LSI) input data" is performed after the transmission data is received by the drum device board 602 and before the transmission data is sent to the door relay board 603. This is performed on the device board 602 (second HB-LSI 612).

The display data set to "Slave 2 (3rd HB-LSI) input data" is input to the "PI0" to "PI15" terminals of the 3rd HB-LSI 613 (PIO circuit 705) mounted on the door relay board 603. It is data. That is, "slave 2 (third HB-LSI) input data" is input from peripheral devices such as the medal sensor 31S and stop switch 8S (see FIG. 133) connected to the door relay board 603 (PIO circuit 705). Data (detection signal) is set. The setting process for "slave 2 (third HB-LSI) input data" is performed after the transmission data is received by the door relay board 603 and before the transmission data is sent to the main control board 601. 603 (third HB-LSI 613).

In addition, in the third gaming machine, as mentioned above, since the HB-LSI corresponding to "slave 3" and "slave 4" is not provided, the 2-byte "slave 3 (spare) input data" and " The slave 4 (preliminary) input data is unused (not updated even during transmission), and any data can be set to these input data. In the third gaming machine, a 2-byte "slave" is included in the transmission data so that it can be applied even when an HB-LSI that is set as a slave is further provided in the main control unit 600 due to function expansion etc. 3 (spare) input data" and "slave 4 (spare) input data". Therefore, when only two HB-LSIs configured as slaves are provided in the main control unit 600, "slave 3 (spare) input data" and "slave 4 (spare) input data" are included in the transmission data. A configuration may also be adopted in which it is not provided.

(CRC16)
The data set in "CRC16" is 2-byte error detection code data for detecting abnormalities that occur during data communication. The data set in "CRC16" is read by the HB-LSI 700 that has received the transmission data, and is used to determine whether a data communication error has occurred.

Furthermore, when transmitting transmission data, the HB-LSI 700 of each board uses a CRC generation circuit (not shown) in the serial bus communication circuit 701 based on data other than "CRC16" set in the transmission data at the time of transmission. ) is used to calculate error detection code data, and the calculation result is set in "CRC16". Therefore, when transmitting data from the drum unit board 602 to the door relay board 603, the “slave 1 (second HB-LSI) input data” used to calculate the error detection code data is This becomes the “slave 1 (second HB-LSI) input data” updated on the board 602. In addition, when transmitting data from the door relay board 603 to the main control board 601, "slave 1 (second HB-LSI) input data" and "slave 2 (third HB-LSI) input data" used for calculating error detection code data -LSI) input data" are the "slave 1 (second HB-LSI) input data" updated on the rotation drum device board 602 and the "slave 2 (third HB-LSI) input data" updated on the door relay board 603, respectively. data”.

Note that when the HB-LSI 700 of each board receives transmission data, the CRC check circuit (in the serial bus communication circuit 701) checks whether there is an error in the error detection code data set in "CRC16". (not shown), but if it is determined that there is an error in the check result, the HB-LSI 700 of each board discards the received transmission data.

As described above, in the configuration example 1 of the data transmitted between the boards in the main control unit 600, the configuration (format) of the transmitted data can be changed regardless of whether the gaming machine is a regular gaming machine or a medalless gaming machine. Although an example of the configuration has been described which can also be used, the present invention is not limited to this. For example, when the gaming machine is a normal gaming machine, in the transmission data configuration shown in FIG. 3) may be omitted. For example, if the gaming machine is a medalless gaming machine, in the transmission data configuration shown in FIG. 1-2") may be omitted.

[11-9-2. Data transmission operation example 1 in synchronous serial communication]
Next, an example 1 of the transmission data transmission operation example of the configuration example 1 (FIG. 144) within the main control unit 600 will be described. In addition, in the transmission data transmission operation example 1, the synchronous serial communication is carried out at intervals equal to or shorter than the cycle of periodic interrupt processing performed by the main CPU (1 interrupt time: 1.1172 ms), and is controlled by the controller 706. Ru. In addition, in the transmission data transmission example 1 described below, the size (26 bytes) of the transmission data generated by the main control board 601 (first HB-LSI 611: master) does not change during transmission; A case will be explained in which no transmission error occurs.

First, in the first HB-LSI 611 that has been set as a master, various output data output from the output ports of each slave (circle body board 602 and door relay board 603) and various display data of the information display device 14 are converted into transmission data. set. Specifically, the main CPU uses the memory mapped IO method in the first HB-LSI 611 to output data from "slave 1 (second HB-LSI)" and "slave 2 (third HB-LSI)" in the transmission data shown in FIG. "LSI) output data", "7 segment display data 1-1" to "7 segment display data 1-4 (shared use)", "Status display data (shared use)" and "7 segment display data 2-1" to "7 Data is set in the addresses corresponding to the segment display data 2-3.

At this time, "7-segment display data 1-1" to "7-segment display data 1-4 (shared use)" are set in the first segment registers 0 to 3 (not shown) provided in the first HB-LSI 611, respectively. , "status display data (common use)" are set in the first segment register 4 (not shown) provided in the first HB-LSI 611. Also, at this time, "7 segment display data 2-1" to "7 segment display data 2-3" are set in second segment registers 0 to 2 (not shown) provided in the first HB-LSI 611, respectively. .

Note that when transmitting data from the first HB-LSI 611, "slave 3 (preliminary) output data", "slave 4 (preliminary) output data", "slave 1 (second HB-LSI) input data", "slave 2 (3rd HB-LSI) input data," "Slave 3 (spare) and data," and "Slave 4 (spare) input data" are not subjected to data setting processing. Therefore, in the transmission data at the start of data transmission from the main control board 601 (first HB-LSI 611), "slave 3 (spare) output data", "slave 4 (spare) output data", "slave 1 (second HB-LSI) -LSI) input data,” “Slave 2 (3rd HB-LSI) input data,” “Slave 3 (spare) and data,” and “Slave 4 (spare) input data” are the data stored at that point. Become.

Next, 2-byte error detection code data (CRC16) is calculated using the various data set in the first HB-LSI 611, and the calculation result is set in "CRC16" in the transmission data. When the above-described transmission data setting process (transmission data generation process) is completed in the main control board 601 (first HB-LSI 611), the generated transmission data is transferred to the first HB-LSI 611 (serial bus communication circuit 701). ) is transmitted to the drum unit board 602 (second HB-LSI 612) via an optical fiber cable.

Next, when the second HB-LSI 612 (serial bus communication circuit 701) of the drum unit board 602 receives the transmission data from the main control board 601, the second HB-LSI 612 receives the "slave 1 (slave 1)" included in the transmission data. 2nd HB-LSI) output data” (2 bytes) is set to the “PO0” to “PO15” terminals (output terminals of the PIO circuit 705) of the second HB-LSI 612. Also, at this time, in the second HB-LSI 612, the detection data of various peripheral devices (reels, etc.) read through the "PI0" to "PI15" terminals (input terminals of the PIO circuit 705) are included in the transmission data. "Slave 1 (2nd HB-LSI) input data" is set.

Next, in the second HB-LSI 612, error detection code data (CRC16) is calculated using the various data set in the transmission data at this point, and the calculation result is set in "CRC16" in the transmission data. As a result, "CRC16" in the transmission data is updated. After the above processing in the second HB-LSI 612 is completed, the transmission data with new data set in "slave 1 (second HB-LSI) input data" is transferred to the second HB-LSI 612 ( The signal is transmitted from the serial bus communication circuit 701) to the door relay board 603 (third HB-LSI 613) via an optical fiber cable.

Next, when the third HB-LSI 613 (serial bus communication circuit 701) of the door relay board 603 receives the transmission data from the drum unit board 602, the third HB-LSI 613 receives the "slave 2 (slave 2)" included in the transmission data. 3rd HB-LSI) output data" (2 bytes) is set to the "PO0" to "PO15" terminals (output terminals of the PIO circuit 705) of the third HB-LSI 613. At this time, in the third HB-LSI 613, the detection data of various peripheral devices (various sensors, various switches, etc.) read through the "PI0" to "PI15" terminals (input terminals of the PIO circuit 705) are transmitted data. This is set to "Slave 2 (3rd HB-LSI) input data" in "Slave 2 (third HB-LSI) input data".

Further, when the third HB-LSI 613 (serial bus communication circuit 701) receives the transmission data, the third HB-LSI 613, under the control of the controller 706, displays various 7-segment display data and status display data included in the transmission data. They are read in the order they are received. Next, each of the read 7-segment display data (1 byte) is converted into character data in the third HB-LSI 613 under the control of the controller 706, and the converted display data is input to the LED drive circuit 703. The read status display data (1 byte) is also input to the LED drive circuit 703.

Note that the type of 7-segment display data read by the third HB-LSI 613 differs depending on the type of gaming machine. Specifically, when the gaming machine is a normal gaming machine, among the various 7-segment display data included in the transmission data, "7-segment display data 1-1" to "7-segment display data 1-4 ( "7-segment display data 1-3 (common use)", "7-segment display data 1-4 (common use)" and "7-segment display data" are read if the gaming machine is a medalless gaming machine. 2-1" to "7-segment display data 2-3" are read. Further, the "status display data (common use)" included in the transmission data is read by the third HB-LSI 613 regardless of the type of gaming machine.

Next, in the third HB-LSI 613, error detection code data (CRC16) is calculated using the various data set in the transmission data at this point, and the calculation result is set in "CRC16" in the transmission data. As a result, "CRC16" in the transmission data is updated. Then, after the above processing in the third HB-LSI 613 is completed, the transmission data with new data set in "slave 2 (third HB-LSI) input data" is transferred to the third HB-LSI 613 (serial) of the door relay board 603. The data is transmitted from the bus communication circuit 701) to the main control board 601 (first HB-LSI 611) via an optical fiber cable.

Next, when the first HB-LSI 611 (serial bus communication circuit 701) of the main control board 601 receives the transmission data from the door relay board 603, the main CPU transmits the data from the first HB-LSI 611 to the bus 606 (data bus and address The data set in "Slave 1 (2nd HB-LSI) input data" and "Slave 2 (3rd HB-LSI) input data" in the transmission data is read (obtained) via the transmission data (including the bus). . This allows the main CPU to grasp the status of external peripheral devices (hopper device, reel, various sensors, various switches, etc.). Also, when the transmission data is received by the first HB-LSI 611, the main CPU outputs "slave 1 (second HB-LSI) output data" and "slave 2 (third HB-LSI) output data" in the transmission data. By reading the set data, it can be confirmed whether the control signals are normally output from the output ports PO0 to PO15 of the second HB-LSI 612 and the third HB-LSI 613.

[11-9-3. Example 2 of data structure transmitted by synchronous serial communication]
The configuration of data transmitted between boards within the main control unit 600 and its transmission mode are not limited to the configuration example 1 and the transmission operation example 1 described above. For example, data transmission between the first HB-LSI 611 set as a master and the second HB-LSI 612 and third HB-LSI 613 set as slaves may be performed separately for each slave. In this case, the address of the destination HB-LSI 700 is specified, and transmission data is sent and received for each destination. In the second configuration example as well, the transmission direction of the transmission data is from the main control board 601 to the rotation device board 602 and the door relay board 603 and back to the main control board 601.

FIG. 145 is a diagram showing a second configuration example of data transmitted by synchronous serial communication between the main control board 601, the drum unit board 602, and the door relay board 603. FIG. 145A is a diagram showing the configuration of data (hereinafter referred to as "master transmission data") transmitted from the main control board 601 to the drum unit board 602 or the door relay board 603 by synchronous serial communication, and FIG. 145B is , is a diagram showing the configuration of data (hereinafter referred to as "slave transmission data") transmitted from the drum device board 602 or the door relay board 603 to the main control board 601 by synchronous serial communication.

In addition, in FIG. 145, as in FIG. 144, for convenience of explanation, the input/output data for peripheral devices set in the transmission data is not only the value of the transmitted data ("value" in the diagram), but also each The name indicating the type of data ("output data", "input data" in the figure), the storage area (RAM and registers) ("FE**H", "FE##H", "FE$$H", "FE&&H" in the diagram) and ports to which each data is input/output ("PO0" in the diagram) etc.) are also listed.

In FIG. 145A, "FE**H" and "FE##H" indicating the address of each storage area of 2-byte output data differ depending on the type of slave to which the output data is transmitted. For example, if the destination slave is the second HB-LSI 612 (slave 1), "FE**H" and "FE##H" become "FED0H" and "FED1H", respectively, and the destination When the slave is the third HB-LSI 613 (slave 2), "FE**H" and "FE##H" become "FED2H" and "FED3H", respectively (see FIG. 144).

In addition, in FIG. 145B, "FE$$H" and "FE&&H" indicating the address of each storage area of 2-byte input data differ depending on the type of slave that is the source of the input data. For example, when the slave that is the transmission source is the second HB-LSI 612 (slave 1), "FE$$H" and "FE&&H" become "FEF0H" and "FEF1H", respectively, and the slave that is the transmission source is In the case of the third HB-LSI 613 (slave 2), "FE$$H" and "FE&&H" become "FEF2H" and "FEF3H", respectively (see FIG. 144).

In addition, in FIG. 145, for convenience of explanation, the display data of the information display device 14 set in the transmission data includes not only the value of the display data ("value" in the figure: "00H to FFH") but also each display data. A name indicating the type of data (such as "7-segment display data 1-1" in the figure), a storage area for each display data in the master (1st HB-LSI 611) that is the source and final destination of the display data. (RAM or register) address (such as "FED4H" in the diagram) and the type of 7-segment LED and lamp displayed for each display data (such as "2-digit 7-seg for credit display" in the diagram) are also listed. There is.

(Master transmission data)
As shown in FIG. 145A, the master transmission data includes, from the beginning, 1 byte of data called "destination address data," 1 byte of data called "source address data," and 2 bytes of data called "output data." Byte data, 1 byte data each called "7 segment display data 1-1" to "7 segment display data 1-4 (shared use)", 1 byte data called "status display data (shared use)", " 1-byte data each called ``7-segment display data 2-1'' to ``7-segment display data 2-3'' and 2-byte data called ``CRC16'' are arranged in this order. That is, in configuration example 2, the size of the data portion (data length) is 14 bytes.

Note that in configuration example 2, as shown in FIG. 145A, even when the destination slave is the second HB-LSI 612 (slave 1) that is not connected to the information display device 14, the display data of the information display device 14 is included in the master transmission data, and the reason for this is as follows. The HB-LSI 700 that has received the master transmission data cannot determine whether or not its built-in LED drive circuit 703 is connected to the information display device 14, regardless of the slave type. Therefore, regardless of whether the transmission destination is slave 1 or slave 2, the display data of the information display device 14 is transmitted to the slave of the transmission destination in order to enable both slaves to use master transmission data in the same format. Regardless of the type of data, it is included in the master transmission data as common data. Note that the present invention is not limited to this, and the master transmission data for slave 1 and the master transmission data for slave 2 may be configured in separate formats. In this case, the master transmission data for slave 1 The data does not need to include display data of the information display device 14.

In addition, in configuration example 2, an example will be described in which spare output data ("slave 3 (spare) output data" and "slave 4 (spare) output data" in FIG. 144) is not included in the master transmission data. The present invention is not limited to this. Preliminary output data may be included in the master transmission data so that it can be applied even when the number of HB-LSIs set as slaves in the main control unit 600 increases due to functional expansion or the like.

(destination address data, source address data)
The "destination address data" and "source address data" in the master transmission data include the voltage application mode (3-bit data) to the "S0" to "S2" terminals of each HB-LSI 700 (PIO circuit 705). The address (“00H” to “07H”) set by the corresponding address is set.

Specifically, in the first HB-LSI 611, which is the master, 5V is applied to the "S0" to "S2" terminals (see FIG. 131), so the address data of the first HB-LSI 611 is "07H" (= " 111B”). In the second HB-LSI 612, which is slave 1, 5V is applied to the "S0" terminal, and the "S1" and "S2" terminals are grounded (see Figure 132), so the address data of the second HB-LSI 612 is "04H". ” (=“100B”). Furthermore, in the third HB-LSI 613, which is slave 2, 5V is applied to the "S0" and "S1" terminals, and the "S2" terminal is grounded (see Figure 133), so the address data of the third HB-LSI 613 is It becomes "06H" (="110B").

Therefore, when transmitting master transmission data from the main control board 601 (master) to the drum unit board 602 (slave 1), "04H" is set in the "destination address data" in the master transmission data. , "07H" is set in "sender address data". On the other hand, when transmitting master transmission data from the main control board 601 (master) to the door relay board 603 (slave), "06H" is set in "destination address data" in the master transmission data, "Original address data" is set to "07H".

(output data)
In "output data" in the master transmission data, output data corresponding to the type of slave that is the transmission destination is set.

For example, when transmitting master transmission data from the main control board 601 (master) to the drum unit board 602 (slave 1), the "output data" in the master transmission data includes configuration example 1 shown in FIG. Data similar to "slave 1 (second HB-LSI) output data" in the transmission data is set. On the other hand, when transmitting master transmission data from the main control board 601 (master) to the door relay board 603 (slave 2), the "output data" in the master transmission data includes the transmission of configuration example 1 shown in FIG. Data similar to "slave 2 (third HB-LSI) output data" in the data is set.

(7 segment display data 1-1 to 7 segment display data 1-4 (common use))
"7-segment display data 1-1" to "7-segment display data 1-4 (shared use)" in the master transmission data are, for example, "7-segment display data 1-4 (shared use)" in the transmission data of configuration example 1 shown in FIG. The same data as "data 1-1" to "7-segment display data 1-4 (common use)" is set.

That is, "7-segment display data 1-1" and "7-segment display data 1-2" in the master transmission data include the information display device 14 (FIG. 125A) used when the gaming machine is a normal gaming machine. The display data of the credit display lamp (2-digit 7-segment LED) and payout display lamp (2-digit 7-segment LED) in (see) are set. In addition, "7-segment display data 1-3 (common use)" and "7-segment display data 1-4 (common use)" in the master transmission data are stored in the information display device 14 (Fig. 125) regardless of the type of gaming machine. and the display data of the instruction monitor in (see FIG. 126) are set.

(Status display data (also used))
For example, the same data as the "status display data (common use)" in the transmission data of configuration example 1 shown in FIG. 144 is set in "status display data (common use)" in the master transmission data. In other words, display data for various status display lamps in the information display device 14 (see FIGS. 125 and 126) is set in the "status display data (common use)" in the master transmission data, regardless of the type of gaming machine. Ru. Note that if the gaming machine is a medalless gaming machine, the least significant bit in the "status display data (also used)" is unused.

(7 segment display data 2-1 to 7 segment display data 2-3)
“7-segment display data 2-1” to “7-segment display data 2-3” in the master transmission data are, for example, “7-segment display data 2-3” in the transmission data of configuration example 1 shown in FIG. Data similar to "1" to "7 segment display data 2-3" are set. That is, "7-segment display data 2-1" to "7-segment display data 2-3" in the master transmission data contain the information display device 14 (see FIG. 126) used when the gaming machine is a medalless gaming machine. ) The 5-digit 7-segment LED display data is set.

(CRC16)
“CRC16” in the master transmission data includes “output data”, “7 segment display data 1-1” to “7 segment display data 1-4 (shared use)”, “status display data (shared use)” and “7 segment display data 1-1” to “7 segment display data 1-4 (shared use)” 2-byte error detection code data calculated using "segment display data 2-1" to "7-segment display data 2-3" is set.

As described above, in the second configuration example of data transmitted between boards in the main control unit 600, the configuration (format) of the master transmission data is changed regardless of whether the gaming machine is a regular gaming machine or a medalless gaming machine. Although an example of the configuration has been described that can be used even in the case of a computer, the present invention is not limited thereto. For example, when the gaming machine is a normal gaming machine, in the transmission data configuration shown in FIG. 3) may be omitted. For example, when the gaming machine is a medalless gaming machine, in the transmission data configuration shown in FIG. 1-2") may be omitted.

(slave transmission data)
As shown in FIG. 145B, the slave transmission data includes, from the beginning, 1 byte of "destination address data", 1 byte of "source address data", 2 bytes of data called "input data", and A 2-byte "CRC16" is arranged in this order. That is, in configuration example 2, the size of the data portion (data length) is 6 bytes.

In addition, in configuration example 2, an example will be described in which the slave transmission data does not include spare input data ("slave 3 (spare) input data" and "slave 4 (spare) input data" in FIG. 144). However, the present invention is not limited thereto. Preliminary input data may be included in the slave transmission data so that it can be applied even when the number of HB-LSIs set as slaves in the main control unit 600 increases due to functional expansion or the like.

(destination address data, source address data)
Address data of the master (first HB-LSI 611) that is the destination is set in "destination address data" in the slave transmission data. Specifically, the address "07H" of the main control board 601 (master) is set in the "destination address data" in the slave transmission data.

Address data of the slave (HB-LSI) serving as the transmission source is set in "source address data" in the slave transmission data. Specifically, when transmitting slave transmission data from the reel device board 602 (slave 1) to the main control board 601 (master), the address data "04H" of the second HB-LSI 612 is set to "source address data". ” is set. On the other hand, when transmitting slave transmission data from the door relay board 603 (slave 2) to the main control board 601 (master), the address data "06H" of the third HB-LSI 613 is set to the "sender address data". Ru.

(Input data)
Input data corresponding to the type of slave serving as the transmission source is set in "input data" in the slave transmission data.

When transmitting slave transmission data from the drum unit board 602 (slave 1) to the main control board 601 (master), the "input data" in the transmission data includes, for example, the transmission of configuration example 1 shown in FIG. Data similar to "slave 1 (second HB-LSI) input data" in the data is set. That is, in this case, in the second HB-LSI 612, the detection data of various peripheral devices (such as reels) read through the "PI0" to "PI15" terminals (input terminals of the PIO circuit 705) are included in the slave transmission data. is set to the "input data" of

On the other hand, when transmitting slave transmission data from the door relay board 603 (slave 2) to the main control board 601 (master), the "input data" in the transmission data includes, for example, the configuration example 1 shown in FIG. Data similar to "slave 2 (third HB-LSI) input data" in the transmission data is set. That is, in this case, in the third HB-LSI 613, the detection data of various peripheral devices (various sensors, various switches, etc.) read through the "PI0" to "PI15" terminals (input terminals of the PIO circuit 705) are Set to "input data" in slave transmission data.

(CRC16)
2-byte error detection code data calculated using the "input data" is set in "CRC16" in the slave transmission data.

[11-9-4. Data transmission operation example 2 in synchronous serial communication]
Next, a second example of the transmission operation of transmission data in the second configuration example (FIG. 145) within the main control unit 600 will be described. In addition, in the transmission data transmission operation example 2, the synchronous serial communication is carried out at an interval equal to or shorter than the cycle of periodic interrupt processing performed by the main CPU (1 interrupt time: 1.1172 ms), and is executed and controlled by the controller 706. Ru. Furthermore, in a second transmission operation example of transmission data to be described below, a case will be described in which a transmission error does not occur during transmission of transmission data.

In addition, in the transmission data transmission operation example 2, the master transmission data transmission operation performed when the transmission destination is slave 1 and the master transmission data transmission operation performed when the transmission destination is slave 2 are continuous. shall be carried out. Note that at this time, the order of the former data transmission operation and the latter data transmission operation is arbitrary. Furthermore, the present invention is not limited to this, and the former data transmission operation and the latter data transmission operation are not performed consecutively, but are performed independently and periodically (at an interval equal to or less than the cycle of periodic interrupt processing). It may be configured to do so.

In addition, in the transmission data transmission operation example 2, the transmission operation of slave transmission data from slave 1 to the master starts when slave 1 receives master transmission data, and the transmission of slave transmission data from slave 2 to the master starts when slave 1 receives master transmission data. It is assumed that the operation starts when slave 2 receives master transmission data. Note that the present invention is not limited to this, and the transmission operation of slave transmission data in each slave is performed independently and periodically (at an interval equal to or shorter than the cycle of periodic interrupt processing), regardless of the reception timing of master transmission data. It may also be done in the following manner.

(Data transmission operation when the destination of master transmission data is slave 1)
First, a data transmission operation when transmitting master transmission data from the main control board 601 (master) to the drum unit board 602 (slave 1) will be described.

First, in the main control board 601 (first HB-LSI 611), the address (04H) of slave 1 (second HB-LSI 612) is set to the "destination address" in the master transmission data, and the master (first HB-LSI 611) address (07H) is set to the "sender address".

Next, in the main control board 601 (first HB-LSI 611), the data output from the output port of slave 1 (second HB-LSI 612) is set to "output data" in the master transmission data using the memory mapped IO method. , the display data of the information display device 14 is "7 segment display data 1-1" to "7 segment display data 1-4 (shared use)", "status display data (shared use)" and "7 segment display data" in the master transmission data. Display data 2-1" to "7-segment display data 2-3" are set.

At this time, "7-segment display data 1-1" to "7-segment display data 1-4 (shared use)" are set in the first segment registers 0 to 3 (not shown) provided in the first HB-LSI 611, respectively. , "status display data (common use)" are set in the first segment register 4 (not shown) provided in the first HB-LSI 611. Also, at this time, "7 segment display data 2-1" to "7 segment display data 2-3" are set in second segment registers 0 to 2 (not shown) provided in the first HB-LSI 611, respectively. . Note that since the information display device 14 is not connected to the drum unit board 602 (slave 1), any data can be set as the display data of the information display device 14.

Next, 2-byte error detection code data (CRC16) is calculated using the various data set in the first HB-LSI 611, and the calculation result is set in "CRC16" in the master transmission data. When the above-described master transmission data setting process (master transmission data generation process) is completed in the main control board 601 (first HB-LSI 611), the generated master transmission data is transferred to the first HB-LSI 611 (serial bus The signal is transmitted from the communication circuit 701) to the drum device board 602 (second HB-LSI 612) via an optical fiber cable.

Next, when the second HB-LSI 612 (serial bus communication circuit 701) of the drum device board 602 receives the master transmission data, the second HB-LSI 612 receives the "destination address" data included in the master transmission data. The address is read and a process is performed to determine whether or not it is the own address (04H). Then, if the "destination address" data is its own address, the "output data" included in the master transmission data is read, and if the "destination address" data is not its own address, the The master transmission data is transferred to the door relay board 603 without the "output data" being read by the 2HB-LSI 612.

In the operation example being explained now, the "destination address" data is the address of itself (second HB-LSI 612), so the "output data" included in the master transmission data is read in the second HB-LSI 612. Then, the "output data" is set to the "PO0" to "PO15" terminals (output terminals of the PIO circuit 705) of the second HB-LSI 612.

At this time, the display data included in the master transmission data is also read into the LED drive circuit 703 in the second HB-LSI 612, but since the information display device 14 is not connected to the second HB-LSI 612, the LED The control in the drive circuit 703 is idle control.

In addition, the second HB-LSI 612 that has received the master transmission data addressed to slave 1 sets the address (07H) of the master (first HB-LSI 611) to the "destination address" in the slave transmission data, and its own address ( 04H) is set in the "source address". Next, in the second HB-LSI 612, the detection data of various peripheral devices (reels, etc.) read through the "PI0" to "PI15" terminals (input terminals of the PIO circuit 705) are stored as "input data" in the slave transmission data. ” is set.

Next, in the second HB-LSI 612, error detection code data (CRC16) is calculated using the various data set in the slave transmission data, and the calculation result is set in "CRC16" in the slave transmission data. When the slave transmission data setting process (transmission data generation process) is completed, the generated slave transmission data is transferred from the drum unit board 602 (second HB-LSI 612) to the door relay board via the optical fiber cable. 603 (third HB-LSI 613).

Next, when the third HB-LSI 613 (serial bus communication circuit 701) of the door relay board 603 receives the slave transmission data from the drum unit board 602, the third HB-LSI 613 receives the "transmission data" included in the slave transmission data. The data of "destination address" is read, and a process of determining whether or not it is the own address (06H) is performed. In the operation example being explained now, the data of the "destination address" is not the address of itself (3rd HB-LSI 613), so the "input data" included in the slave transmission data is read by the 3rd HB-LSI 613. The slave transmission data is transferred to the main control board 601 without being sent.

Next, when the slave transmission data transferred from the door relay board 603 is received by the first HB-LSI 611 (serial bus communication circuit 701) of the main control board 601, the slave transmission data included in the slave transmission data is The data of "destination address" is read, and a process is performed to determine whether it is the own address (07H). In the operation example currently being described, the data of the "destination address" is the address of itself (first HB-LSI 611), so in the first HB-LSI 611, the "input data" ( Detection data of various peripheral devices (reels, etc.) are read.

Then, the main CPU acquires the read "input data" (detection data of various peripheral devices (reels, etc.)) from the first HB-LSI 611 via the bus 606 (including a data bus and an address bus). Thereby, the main CPU can grasp the status of various peripheral devices (such as reels) connected to the rotating drum device board 602.

(Communication operation when the destination of master transmission data is slave 2)
Next, a data transmission operation when transmitting master transmission data from the main control board 601 (master) to the door relay board 603 (slave 2) will be described.

First, in the main control board 601 (first HB-LSI 611), the address (06H) of slave 2 (third HB-LSI 613) is set to the "destination address" in the master transmission data, and the master (first HB-LSI 611) address (07H) is set to the "sender address".

Next, in the main control board 601 (first HB-LSI 611), the data output from the output port of slave 2 (third HB-LSI 613) is set to "output data" in the master transmission data using the memory mapped IO method. , the display data of the information display device 14 is "7 segment display data 1-1" to "7 segment display data 1-4 (shared use)", "status display data (shared use)" and "7 segment display data" in the master transmission data. Display data 2-1" to "7-segment display data 2-3" are set.

Next, 2-byte error detection code data (CRC16) is calculated using the various data set in the first HB-LSI 611, and the calculation result is set in "CRC16" in the master transmission data. When the above-described master transmission data setting process (master transmission data generation process) is completed in the main control board 601 (first HB-LSI 611), the generated master transmission data is transferred to the first HB-LSI 611 (serial bus The signal is transmitted from the communication circuit 701) to the drum device board 602 (second HB-LSI 612) via an optical fiber cable.

Next, when the second HB-LSI 612 (serial bus communication circuit 701) of the drum device board 602 receives the master transmission data, the second HB-LSI 612 receives the "destination address" data included in the master transmission data. The address is read and a process is performed to determine whether or not it is the own address (04H). In the operation example being explained now, the data of the "destination address" is not the address of itself (the second HB-LSI 612), so the "output data" included in the master transmission data is The master transmission data is not read and is transmitted (transferred) to the door relay board 603.

Next, when the master transmission data transmitted (transferred) from the drum device board 602 is received by the third HB-LSI 613 (serial bus communication circuit 701) of the door relay board 603, the master transmission data is transmitted in the third HB-LSI 613. The "destination address" data included in the address is read, and a determination process is performed to determine whether it is the own address (06H).

In the operation example being explained now, the data of the "destination address" is the address of itself (3rd HB-LSI 613), so in the 3rd HB-LSI 613, the "output data" included in the master transmission data is The "output data" is read and set to the "PO0" to "PO15" terminals (output terminals of the PIO circuit 705) of the third HB-LSI 613.

Also, at this time, the third HB-LSI 613 reads various display data included in the master transmission data, and inputs the various display data to the LED drive circuit 703 in the third HB-LSI 613. In the third gaming machine, since the information display device 14 is connected to the third HB-LSI 613, the display operation of the information display device 14 is controlled based on various input display data. Note that at this time, the type of display data read by the third HB-LSI 613 differs depending on the type of gaming machine. Specifically, when the gaming machine is a normal gaming machine, among the various display data included in the master transmission data, "7 segment display data 1-1" to "7 segment display data 1-4 (also used )" and "Status display data (common use)" are read, and if the gaming machine is a medalless gaming machine, "7 segment display data 1-3 (common use)" and "7 segment display data 1-4 (common use)" are read. )", "Status display data (common use)", and "7-segment display data 2-1" to "7-segment display data 2-3" are read.

In addition, the third HB-LSI 613 that has received the master transmission data addressed to the slave 2 sets the address (07H) of the master (first HB-LSI 611) to the "destination address" in the slave transmission data, and its own address ( 06H) is set in the "source address". Next, in the third HB-LSI 613, the detection data of various peripheral devices (various sensors, various switches, etc.) read through the "PI0" to "PI15" terminals (input terminals of the PIO circuit 705) are stored in the slave transmission data. is set to the "input data" of

Next, in the third HB-LSI 613, error detection code data (CRC16) is calculated using the various data set in the slave transmission data, and the calculation result is set in "CRC16" in the slave transmission data. When the slave transmission data setting process (transmission data generation process) is completed, the generated slave transmission data is transferred from the door relay board 603 (third HB-LSI 613) to the main control board 601 via the optical fiber cable. (first HB-LSI 611).

Next, when the slave transmission data transmitted from the door relay board 603 is received by the first HB-LSI 611 (serial bus communication circuit 701) of the main control board 601, the slave transmission data included in the slave transmission data is The data of "destination address" is read, and a process is performed to determine whether it is the own address (07H). In the operation example currently being described, the data of the "destination address" is the address of itself (first HB-LSI 611), so in the first HB-LSI 611, the "input data" ( Detection data of various peripheral devices (various sensors, various switches, etc.) are read.

Then, in the main CPU, the "input data" (detection data of various peripheral devices (various sensors, various switches, etc.)) read from the first HB-LSI 611 via the bus 606 (including the data bus and address bus) is processed. be obtained. Thereby, the main CPU can grasp the status of various peripheral devices (various sensors, various switches, etc.) connected to door relay board 603.

[11-10. Various effects obtained with the third gaming machine]
In the third gaming machine, as described above, an input/output port is provided on each relay board in the main control unit 600, and the input/output port is connected to the input/output port of external peripheral devices (reels, various switches, various sensors, etc.). equipment) is connected, and communication cables are used to connect the main control board 601 and each relay board. Therefore, in the third gaming machine, the number of connection ports (input/output ports) with external peripheral devices provided on the main control board 601 can be reduced, thereby reducing the size of the main control board 601. be able to.

Further, in the third gaming machine, the main control board 601 and each relay board are connected by communication cables. Therefore, in the third gaming machine, the number of harnesses connecting between the main control board 601 and each relay board can be reduced.

Furthermore, in the third gaming machine, external peripheral devices are connected to the input/output ports of each relay board. Therefore, in the third gaming machine, the length of the wiring cable connecting the external peripheral device and the input/output port to which it is connected can be shortened.

Furthermore, as explained in FIG. 141, in conventional gaming machines (for example, see Japanese Patent Laid-Open No. 2018-027130), generated command data is stored using the RAM (main RAM) on the main control side. There is a need. Furthermore, as a limitation unique to gaming machines, the capacity that can be used in the main RAM of the main control device is limited to a small capacity by regulations. Therefore, in a configuration in which the main RAM is used to store command data like a conventional gaming machine, the capacity of the main RAM for use in other processes is compressed.

On the other hand, in the third gaming machine, as described above, when transmitting data from the main control unit 600 to the sub-control unit 620 (asynchronous serial communication), the first HB-LSI 611 mounted on the main control board 601 The generated command data is stored in the data buffer (transmission data buffer 718) (see FIGS. 142 and 142), and then the command data is transmitted. That is, in the third gaming machine, a data buffer (storage area for transmission data) used for communication is provided outside the microprocessor (main RAM) mounted on the main control board 601. Therefore, in the third gaming machine, there is no need to secure a storage area (storage area) for data to be sent to the sub-control unit 620 in the main RAM in the microprocessor, and that area can be used for processing the gaming experience. It can be assigned to the work area used in . As a result, in the third gaming machine, it is possible to alleviate the pressure on the main RAM capacity caused by limitations specific to gaming machines.

In addition, in the configuration of conventional general gaming machines, the required number of ICs (Integrated Circuits) for PIO circuits are mounted on the main control board, and the main control board is connected directly or indirectly (relay board) to the reels, switches, etc. (via). In contrast, in the configuration of the third gaming machine described above, one HB-LSI 700 (first HB-LSI 611) provided on the main control board 601 connects the reels, switches, etc. directly or indirectly. Therefore, compared to conventional general gaming machines, the configuration is simpler and costs can be reduced.

In addition, as mentioned above, each board on the main side of a conventional gaming machine includes an ASIC (master) equipped with a random number generation circuit, a PIO circuit, and a serial bus communication circuit between the master and slave, a PIO circuit, and a serial bus communication circuit between the master and slave. An ASIC (slave) that includes a serial bus communication circuit and an LED drive circuit, and an ASIC (security LSI) that includes an asynchronous serial communication circuit (encrypted communication circuit) between the main and sub are provided separately. The configuration of the HB-LSI 700 mounted on each board on the main side of the gaming machine No. 3 is a configuration in which these three types of conventional ASICs are combined into one. Therefore, in the third gaming machine, the configuration can be further simplified and the cost can be further reduced compared to conventional general gaming machines. Furthermore, in the third game machine, all the HB-LSIs 700 mounted on each board have the same configuration (specifications), so that costs can be further reduced.

Furthermore, conventionally, when performing synchronous serial communication between the master and slave between boards in the main control unit, a technology has been proposed in which one error detection code data (CRC) is added to every 2 bytes of data. In the third gaming machine, as described above, one error detection code data (CRC16) is added to each packet of gaming control data group. Therefore, in the third gaming machine, the capacity of transmission data transmitted and received through synchronous serial communication between the master and slave can be reduced compared to the above-mentioned conventional technology.

[11-11. Additional notes]
Conventional gaming machines have been proposed in which input/output ports, basic random number generators, etc. are connected to the main controller's CPU (Central Processing Unit) via an internal bus (for example, Japanese Patent Laid-Open No. 2009-268481) (see official bulletin).

However, for example, in the gaming machine disclosed in Japanese Patent Application Laid-open No. 2009-268481, the main controller is provided with an input/output port. output devices must be connected via a wiring cable (for example, a so-called flat cable that can be connected with a harness). Therefore, in the configuration of the conventional gaming machine, there was a problem that the number of wiring cables connected to the board increased, and the size of the board of the main control device became large. Further, in the configuration of the conventional gaming machine, there was also a problem that the wiring cable between the board of the main control device and the peripheral devices became long.

The present invention has been made in view of these points, and provides a game in which the board size of the main control section can be reduced, and the length of the wiring cable connecting the main control section and peripheral devices can also be shortened. The purpose is to provide a machine.

In order to achieve the above object, according to the gaming machine according to the present embodiment, a gaming machine having the following configuration can be provided.

A main control unit (for example, main control unit 600) that controls the progress of the game,
a sub-control unit (for example, sub-control unit 620) that controls the production device according to instructions from the main control unit;
a plurality of peripheral devices connected to the main control unit and capable of inputting and/or outputting signals to and from the main control unit,
The main control unit includes at least a main control board and a plurality of relay boards (for example, a drum unit board 602 and a door relay board 603),
Each of the main control board and the plurality of relay boards includes a signal input/output unit (for example, a PIO circuit 705) that inputs and outputs the signal, and a first communication unit that can communicate with the outside using a first communication method. (e.g., serial bus communication circuit 701) and a second communication unit (e.g., asynchronous serial communication circuit 702) that can communicate with the outside using a second communication method (e.g., HB-LSI 700) is implemented,
Each of the plurality of peripheral devices is connectable to the signal input/output section of the input/output communication means,
Between the main control board and the relay board, the first communication unit built in the input/output communication means of the main control board and the first communication unit built in the input/output communication means of the relay board are connected. A game machine characterized in that it is possible to perform communication by connecting with.

In the game machine of the present invention, the plurality of peripheral devices include an information display device capable of displaying information including the number of stored game values;
The input/output communication means includes a display drive section (e.g., LED drive circuit 703) capable of displaying the information on the information display device, and a random number generation section (e.g., , random number generation circuit 708) may be further incorporated.

In the gaming machine of the present invention, the first communication method is a synchronous serial communication method, and the second communication method is an asynchronous serial communication method,
The second communication section built in the input/output communication means of the main control board may be connected to the sub-control section so that they can communicate with each other.

In the gaming machine of the present invention, the signal input/output section built into the input/output communication means includes a plurality of input terminals (for example, "S0" to "S2" terminals) for setting the address of the input/output communication means. is established,
The address of the input/output communication means may be set by the manner in which voltage values are applied to the plurality of address setting input terminals.

Further, in the gaming machine of the present invention, the second communication unit includes a first register (e.g., first data set register 711) and a second register (e.g., second data set register 712) in which transmission data is set. and a data buffer (for example, transmission data buffer 718) into which transmission data is written from the first register and the second register,
When transmitting a transmission data group consisting of a plurality of transmission data transmitted in one transmission operation, among the plurality of transmission data included in the transmission data group, transmission data other than the last transmission data is After being set in the first register, the transmission data is written to the data buffer and transmitted last; after being set in the second register, the transmission data is written to the data buffer and transmitted last. After the transmission data is written in the data buffer, the transmission data group written in the data buffer may be transmitted to the outside.

Further, in the gaming machine of the present invention, the gaming machine is a medalless gaming machine,
The information display device may include a 5-digit, 7-segment LED capable of displaying the information.

Furthermore, in the gaming machine of the present invention, the random number generation section includes a random number monitoring section (for example, a random number monitoring circuit 738) that monitors the predetermined period that is an update period of the random number value,
The random number monitoring unit may determine that an abnormality (for example, "decrease in clock signal frequency") has occurred when the random number value is updated for a period longer than a specific period that is longer than the update period. .

In the gaming machine of the present invention, when the abnormality occurs, the random number monitoring unit sets first status information indicating the abnormality and second status information indicating the abnormality history, and then sets the When the abnormality is resolved, the first status information is cleared, but the second status information may not be cleared and held until the power is turned off.

Further, in the gaming machine of the present invention, the first communication unit adds one piece of error detection data (for example, "CRC16") to a group of transmission data transmitted in one transmission operation. Good too.

Furthermore, in the gaming machine of the present invention, the main control board includes an arithmetic processing unit (for example, a main CPU) that performs arithmetic processing for controlling gaming operations, and a A built-in first storage section (e.g., main ROM) in which necessary information is stored, and a second storage section (e.g., main RAM) in which information necessary for execution of the arithmetic processing by the arithmetic processing section is stored. The game control means (eg, microprocessor 610) may be implemented separately from the input/output communication means.

According to the gaming machine of the present invention having the above configuration, the board size of the main control section can be reduced, and the length of the wiring cable connecting the main control section and the peripheral devices can also be shortened.

3L...left reel, 3C...middle reel, 3R...right reel, 14...information display device, 600...main control unit, 601...main control board, 602...reel device board, 603...door relay board, 610...microprocessor , 611...First HB-LSI, 612...Second HB-LSI, 613...Third HB-LSI, 614...Fourth HB-LSI, 615...Sub CPU, 620...Sub control unit, 621...Sub relay board, 622...Sub control Board, 623...VDP board, 650...Medal number control board, 700...HB-LSI, 701...Serial bus communication circuit, 702...Asynchronous serial communication circuit, 703...LED drive circuit, 704...Character data storage unit for 7 segments, 705... PIO circuit, 707... Controller, 707... External bus I/F, 708... Random number generation circuit, 709... Internal bus

Claims (1)

a main control unit that controls the progress of the game;
a sub-control unit that controls the production device in accordance with instructions from the main control unit;
a plurality of peripheral devices connected to the main control unit and capable of inputting and/or outputting signals to and from the main control unit,
The main control unit has at least a main control board and a plurality of relay boards,
Each of the main control board and the plurality of relay boards includes a signal input/output section that inputs and outputs the signal, a communication section that can communicate with the outside using a predetermined communication method, and the signal input/output section and the communication section. and a display drive unit capable of displaying information on an information display device capable of displaying information including the stored number of game values ;
Each of the plurality of peripheral devices is connectable to the signal input/output section of the input/output communication means,
Communication is performed between the main control board and the relay board by connecting the communication section of the input/output communication means of the main control board and the communication section of the input/output communication means of the relay board. It is possible to
The main control board includes an arithmetic processing unit that performs arithmetic processing for controlling gaming operations, a first storage unit that stores information necessary for the arithmetic processing unit to execute the arithmetic processing, and a first storage unit that stores information necessary for the arithmetic processing by the arithmetic processing unit. A game machine characterized in that a game control means having a second storage section in which information necessary for execution of the arithmetic processing by the section is stored is installed separately from the input/output communication means.

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