JP7483268B2 - Gaming Machines - Google Patents

Description

The present invention relates to gaming machines such as pachislot machines and pachinko machines.

Conventionally , so-called medal-less gaming machines have been proposed in which gaming value is provided directly from a medal dispensing device (sand) without the need to insert medals, which are gaming media, into the gaming machine (see, for example, Patent Document 1) .

JP 2019-187818 A

In the gaming machine described in Patent Document 1, a payout control board that controls the counting of the payout amount of game value is attached inside the cabinet, and the switches (buttons) connected to the payout control board include switches that can be operated by an attendant. Therefore, there is a demand for a technology that notifies information on whether such switches have been operated correctly .

The present invention has been made in consideration of these points, and aims to provide a method for reporting information in an amusement machine indicating whether or not an operation on a switch (button) connected to a board that controls the management of game value has been performed accurately .

To achieve the above objective, the gaming machine according to this embodiment can provide a gaming machine having the following configuration:

A game control means (e.g., a main control microprocessor 450 described later) for controlling the progress of the game;
A game value control means (e.g., a medal count control microprocessor 460 described later) connected to the game control means and controlling management of the game value;
A game value display means (e.g., a medal count display unit 426b described later) connected to the game value control means and displaying information related to the game value;
A predetermined operation detection means (e.g., a medal count clear switch 443a described later) connected to the game value control means and capable of detecting a predetermined operation;
A presentation control means (e.g., a sub-CPU described later) connected to the game control means for controlling presentations;
an audio output means (e.g., a speaker included in a speaker group 429 described later) connected to the performance control means and outputting audio;
A display means (e.g., a display device 413 described later) connected to the performance control means and capable of displaying information related to the game,
When the predetermined operation is detected by the predetermined operation detection means, information about the game value displayed on the game value display means can be updated;
The game value control means notifies the game control means of a detection result by the predetermined operation detection means,
In a state where the predetermined operation is detected by the predetermined operation detection means, the game control means notifies the performance control means of predetermined information indicating that the predetermined operation is being performed (for example, a medal count clear start command described later);
When the predetermined operation detection means detects the predetermined operation and then transitions to a state where the predetermined operation is not detected, the game control means notifies the performance control means of specific information (e.g., a medal count clear end command described later) indicating that the predetermined operation has not been performed;
the presentation control means, when notified of the predetermined information by the game control means, controls the sound output means to output a predetermined sound (for example, a medal count clear sound, which will be described later) from the sound output means;
the display means is capable of displaying a menu screen including a plurality of selectable items;
The volume of the audio output means can be adjusted on the menu screen,
When the game control means notifies the performance control means of the predetermined information, if the menu screen is being displayed by the display means, the audio output means does not output the predetermined sound, and the audio output means outputs the predetermined sound after the display of the menu screen is completed.
the performance control means is capable of controlling the sound output means to stop output of the predetermined sound when the specific information is notified from the game control means and the predetermined sound is being output at that time;
The game control means is capable of executing a main control process which is repeated for each unit game, and an interrupt process which is repeated at a predetermined cycle (for example, a cycle of 1.1172 msec, which will be described later);
The processing by the game control means to receive a notification of the detection result by the predetermined operation detection means from the game value control means and to notify the performance control means of the predetermined information or the specific information corresponding to the detection result by the predetermined operation detection means are performed in the interrupt processing.
A gaming machine characterized by:
In the gaming machine configured as described above, information regarding the game value displayed on the game value display means can be updated when a specified operation is detected, so that the operator can be notified of information indicating whether a specified operation (a pressing operation described below) on the specified operation detection means (a medal count clear switch 443a described below) has been performed accurately.
In a gaming machine having the above-mentioned features, for example, the fact that the accumulated number of game values has been cleared by a predetermined operation on the predetermined operation detection means (a medal number clear switch 443a described later) can be notified by the game value display means and also by the audio output means. Therefore, when the above-mentioned features are provided, for example, when a staff member of an amusement facility performs a predetermined operation on the predetermined operation detection means, even if a situation occurs in which it is difficult to visually check the display on the game value display means, the staff member of the amusement facility can be reliably notified that a predetermined operation (valid operation) has been performed on the predetermined operation detection means.
In a gaming machine having the above-mentioned features, for example, a predetermined sound is output after a setting change operation or a setting confirmation operation is completed, so that an attendant at an amusement facility can remember to check (visually) that the accumulated number of gaming values displayed on the 7-segment LED has been cleared.
In a gaming machine having the above-mentioned characteristics, for example, the output of a predetermined sound (medal count clear sound described below) is stopped in conjunction with the completion of a predetermined operation on a predetermined operation detection means (medal count clear switch 443a described below), so that a situation does not occur in which the predetermined sound continues to sound even after the predetermined operation is completed (after the process of clearing the stored number is completed), thereby preventing the occurrence of an unpleasant situation.
Furthermore, in a gaming machine having the above-mentioned features, for example, it is possible to perform a check process of the detection results of the specified operation detection means (for example, the medal count clear check process described below) during the setting change process.

According to the gaming machine of the present invention having the above-described configuration, for example, it is possible to notify the operator of information indicating whether or not an operation on a switch (button) connected to a board that controls the management of gaming value has been performed accurately .

A diagram showing the external structure of the gaming machine according to the present embodiment. 1 is a diagram showing the internal structure of a gaming machine according to an embodiment of the present invention; 2 is a block diagram showing the electrical configuration of the gaming machine according to the present embodiment. FIG. 1 is a diagram for explaining the functional flow of the gaming machine according to the present embodiment. FIG. A diagram for explaining the playability of the first gaming machine according to the present embodiment. 11 is a diagram for explaining the modes of the first gaming machine according to the present embodiment. FIG. 3A to 3C are diagrams showing various tables of the first gaming machine according to the present embodiment. 3A to 3C are diagrams showing various tables of the first gaming machine according to the present embodiment. A figure showing a pattern arrangement table of the first gaming machine related to this embodiment. A figure showing an internal lottery table of the first gaming machine related to the present embodiment. FIG. 2 is a diagram showing a symbol combination table of the first gaming machine according to the present embodiment. FIG. 13 is a diagram showing a symbol combination table of the first gaming machine according to the present embodiment. FIG. 2 is a diagram showing a symbol combination table of the first gaming machine according to the present embodiment. FIG. 13 is a diagram showing a symbol combination table of the first gaming machine according to the present embodiment. 11 is a diagram for explaining the correspondence between the internal winning combinations, the stop operation modes, and the display combinations, etc., of the first gaming machine according to the present embodiment. FIG. A figure for explaining the limit processing of the first gaming machine according to the present embodiment. 1 is a diagram showing the configuration of a winning flag storage area, a winning activation flag storage area, and a pattern code storage area of a first gaming machine according to this embodiment. FIG. A diagram showing the configuration of a carryover role storage area of the first gaming machine according to this embodiment. A diagram showing the configuration of a game status flag storage area of the first gaming machine according to the present embodiment. A diagram showing the configuration of a mode flag storage area of the first gaming machine according to the present embodiment. A diagram showing the configuration of the operation stop button storage area of the first gaming machine according to this embodiment. A diagram showing the configuration of a press sequence storage area of the first gaming machine according to this embodiment. 5 is a flowchart showing a main process executed by a main control circuit of the first gaming machine according to the present embodiment. 5 is a flowchart showing the power-on process executed by the main control circuit of the first gaming machine according to the present embodiment. 11 is a flowchart showing a medal acceptance/start check process executed by a main control circuit of the first gaming machine according to this embodiment. 11 is a flowchart showing an internal lottery process executed by a main control circuit of the first gaming machine according to the present embodiment. 10 is a flowchart showing a game start state control process executed by a main control circuit of the first gaming machine according to the present embodiment. A flowchart showing the processing at the start of play during a favorable zone executed by the main control circuit of the first gaming machine of this embodiment. 10 is a flowchart showing a reel stop control process executed by a main control circuit of the first gaming machine according to the present embodiment. 11 is a flowchart showing a game end state control process executed by a main control circuit of the first gaming machine according to the present embodiment. A flowchart showing the processing at the end of play during a favorable zone executed by the main control circuit of the first gaming machine of this embodiment. 10 is a flowchart showing a periodic interrupt process executed by a main control circuit of the first gaming machine according to the present embodiment. 4 is a flowchart showing an overview of the sub-side control processing executed by the sub-control circuit of the gaming machine according to the present embodiment. FIG. 2 is a diagram showing an example of the configuration of a medalless gaming machine according to the present embodiment. FIG. 2 is a diagram showing an example of the configuration of a main control board of the gaming machine according to the present embodiment. An oblique view showing the external structure of a gaming system including a second gaming machine according to the present embodiment. A figure showing examples of the configuration of a game information display unit, a medal count display unit, and a medal lending display unit provided in a second gaming machine of this embodiment. A diagram showing the internal structure of a second gaming machine according to the present embodiment. A block diagram showing the overall configuration of a control system provided in a second gaming machine according to the present embodiment. A diagram showing an example of installation of a medal count clear switch provided in a second gaming machine according to this embodiment. A block diagram showing the internal configuration of a main control board of a second gaming machine according to the present embodiment. A block diagram showing the internal configuration of a medal count control board of a second gaming machine according to the present embodiment. A block diagram showing the internal configuration of a microprocessor mounted on the main control board and the medal count control board of the second gaming machine of this embodiment. A diagram showing the configuration, installation example, and information display content of the role ratio monitor in the second gaming machine of this embodiment. A diagram showing the general operation of the data communication mechanism and input/output mechanism provided between the main control board, medal count control board, and sub-control board in the second gaming machine of this embodiment. 13 is a timing chart of the lighting control of the line LEDs performed when the 1 bet button is pressed in the second gaming machine according to the present embodiment. 13 is a timing chart of game start control performed when the start lever is operated during settlement in the second gaming machine according to the present embodiment. 13 is a timing chart of the control performed when the upper limit of the medal counter is exceeded in the second gaming machine according to this embodiment. A schematic diagram of a data input/output mechanism provided between a gaming machine and a gaming medium lending device in a gaming system including a second gaming machine according to this embodiment. A figure showing an example of data input/output control between the second gaming machine and the gaming medium lending device in this embodiment. A figure for explaining an overview of the connection confirmation process between the medal count control board and the game media lending device performed at startup in a gaming system including a second gaming machine of this embodiment. A schematic diagram of a data input/output mechanism provided between a gaming machine and a gaming medium lending device in a gaming system including a second gaming machine according to this embodiment. A diagram for explaining an overview of the lending process between the medal count control board and the game media lending device performed during a lending operation in a gaming system including a second gaming machine of this embodiment. A schematic diagram of a data input/output mechanism provided between a gaming machine and a gaming medium lending device in a gaming system including a second gaming machine according to this embodiment. A diagram for explaining an overview of the settlement process between the medal count control board and the game media lending device performed during settlement operations in a gaming system including the second gaming machine of this embodiment. This is a diagram for explaining an overview of the transmission processing between the main control board, the medal count control board, and the gaming medium lending device when transmitting a chip individual number in a gaming system including a second gaming machine of this embodiment. 13 is a flowchart showing an example of a main operation process (main process) executed by a main control board of the second gaming machine according to the present embodiment after power is turned on. 13 is a flowchart showing an example of a power-on process executed by a main control board of the second gaming machine according to the present embodiment. 13 is a flowchart showing an example of a setting change process executed by a main control board of the second gaming machine according to the present embodiment. 13 is a flowchart showing an example of a game start preparation process executed by a main control board of the second gaming machine according to the present embodiment. 13 is a flowchart showing an example of a medal return process executed by a main control board of the second gaming machine according to this embodiment. 13 is a flowchart showing an example of a game start process executed by a main control board of the second gaming machine according to the present embodiment. 13 is a flowchart showing an example of a game ending process executed by a main control board of the second gaming machine according to the present embodiment. A flowchart showing an example of a game medal payout process executed by the main control board of the second gaming machine according to this embodiment. 13 is a flowchart showing an example of a periodic interrupt process executed by a main control board of the second gaming machine according to the present embodiment. 13 is a flowchart showing an example of a medal count clear check process executed by the main control board of the second gaming machine according to this embodiment. 13 is a flowchart showing an example of a reception interrupt process executed by a main control board of the second gaming machine according to the present embodiment. 13 is a flowchart showing an example of a power-on process executed by a medal count control board of the second gaming machine according to the present embodiment. 13 is a flowchart showing an example of a medal count clear switch check process executed by a medal count control board of the second gaming machine according to the present embodiment. 13 is a flowchart showing an example of a peripheral device connection confirmation process executed by the medal count control board of the second gaming machine according to this embodiment. 13 is a flowchart showing an example of a startup command reception process executed by the medal count control board of the second gaming machine according to this embodiment. 13 is a flowchart showing an example of a peripheral device identification code transmission process executed by a medal count control board of the second gaming machine according to this embodiment. 13 is a flowchart showing an example of a setting change reception process executed by the medal count control board of the second gaming machine according to this embodiment. 13 is a flowchart showing an example of processing executed by the medal count control board of the second gaming machine according to this embodiment when a medal insertion request command is received. 13 is a flowchart showing an example of a process executed by the medal count control board of the second gaming machine according to this embodiment when a medal return request command is received. 13 is a flowchart showing an example of a process executed by the medal count control board of the second gaming machine according to this embodiment when a medal payout request command is received. 13 is a flowchart showing an example of processing executed by the medal count control board of the second gaming machine according to this embodiment when the settlement switch is pressed. A flowchart showing an example of processing executed by the medal count control board of the second gaming machine of this embodiment when a medal lending instruction command is received. 13 is a flowchart showing an example of a periodic interrupt process executed by a medal count control board of the second gaming machine according to the present embodiment. 13 is a flowchart showing an example of a process executed by the medal count control board of the second gaming machine according to the present embodiment when game information is received. 13 is a flowchart showing an example of a main control reception interrupt process executed by the medal count control board of the second gaming machine according to this embodiment. 11 is a flowchart showing an example of a power-on process executed by a game medium lending device connected to a second game machine according to the present embodiment. 13 is a flowchart showing an example of a medal count control connection confirmation process executed by a game media lending device connected to a second game machine according to this embodiment. 11 is a flowchart showing an example of a medal lending process executed by a game medium lending device connected to a second gaming machine according to the present embodiment. 11 is a flowchart showing an example of a medal counting (settlement) process executed by a game medium lending device connected to a second game machine according to the present embodiment. 13 is a flowchart showing an example of a process executed by the sub-control board of the second gaming machine according to the present embodiment when a main control command is received. 13 is a flowchart showing an example of processing executed by the sub-control board of the second gaming machine according to this embodiment when a non-game progress command is received. FIG. 11 is a schematic diagram of a first modified example of a gaming system including a second gaming machine according to the present embodiment. FIG. 11 is a schematic diagram of a variant 2 of a gaming system including a second gaming machine according to the present embodiment. FIG. 11 is a schematic diagram of a modified example 3 of a gaming system including the second gaming machine according to the present embodiment. A figure showing an example of level control of two-wire synchronous data communication performed during settlement processing in variant 5 of a gaming system including the second gaming machine of this embodiment. This is a schematic diagram of the disconnection detection circuit provided between the medal count control board and the game media lending device in variant 6 of a gaming system including the second gaming machine of this embodiment. A diagram showing a schematic configuration of a seventh variant of a gaming system including a second gaming machine according to the present embodiment, and a flow of sending and receiving authentication information between component devices.

The gaming machine according to this embodiment will be described below with reference to the drawings. Note that in this embodiment, a pachislot machine will be used as an example of the gaming machine.

[1. Structure of a Pachislot Machine]
First, the structure of the slot machine 1 will be described with reference to Figures 1 and 2. Figure 1 is a diagram showing the external structure of the slot machine 1, and Figure 2 is a diagram showing the internal structure of the slot machine 1. For ease of explanation, the following explanation of the external structure may include a part of the internal structure, and the explanation of the internal structure may include a part of the external structure.

[1-1. External structure]
[1-1-1. Housing]
The slot machine 1 is composed of a rectangular box-shaped housing 2. The housing 2 has a metal cabinet G having a rectangular opening on the front side as the gaming machine main body, an upper door mechanism UD arranged at the upper front part of the cabinet G, and a lower door mechanism DD arranged at the lower front part of the cabinet G.

The cabinet G has an intermediate support plate G1, a pair of left and right side walls G2, a rear wall G3, a top wall G4, and a bottom wall G5. Note that the rear wall G3 and bottom wall G5 are not shown in Figures 1 and 2. The top wall G4 of the cabinet G has two openings G4a that penetrate in the vertical direction and are spaced a certain distance apart in the horizontal direction. Wooden plate members G4b are attached to the top wall G4 so as to close each of the two openings G4a.

The plate member G4b is used to secure the slot machine 1 to the game island (not shown) when it is installed in an amusement facility, and as long as such a method of securing the fastening is ensured, it can be made of metal or resin, or can be formed integrally with the top wall G4. As long as a certain level of strength is ensured for the cabinet G, some or all of the components can be made of wood or resin.

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 G102 that opens forward is formed on the lower side across the intermediate support plate G1. That is, the inside of the cabinet G is divided into an upper space and a lower space across the intermediate support plate G1, and the intermediate support plate G1 functions as a partition plate that divides the inside of the cabinet G into the upper space and the lower space. The upper space is the space behind the upper door mechanism UD in the cabinet G, and contains the main display device 210, which will be described later, and the like. The lower space is the space behind the lower door mechanism DD in the cabinet G, and contains the reel unit RU, the main control board 71, and the like, which will be described later.

The cabinet G does not necessarily have to include the intermediate support plate G1. In other words, as long as each device etc. can be appropriately accommodated within the cabinet G, the cabinet G may not have a partition between the upper and lower spaces. The cabinet G may simply be referred to as a "box" or "main body", or, since it functions as a frame that supports or fixes the upper door mechanism UD and the lower door mechanism DD, it may also be referred to as a "main body frame", "support body", "support frame", "fixing frame", etc.

[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 and lower spaces of the opening in the cabinet G. In other words, the upper door mechanism UD and the lower door mechanism DD function as a front door provided on the front side of the slot machine 1.

The upper door mechanism UD and the lower door mechanism DD are each attached to the cabinet G so as to be freely opened and closed, for example, by an opening and closing mechanism (not shown) such as a hinge provided on the left side wall G2. Note that it is also possible to configure either the upper door mechanism UD or the lower door mechanism DD to be openable and closable by the above-mentioned opening and closing mechanism, while the other can be attached and detached only when one of the door mechanisms is in the open state.

The upper door mechanism UD has a performance display window UD1 provided in the center, and an upper lamp 23 provided above the performance display window UD1. The performance display window UD1 is configured, for example, as a transparent panel made of resin, and allows the performance image displayed on a screen device C that constitutes the main display device 210 (described below) provided on the rear side of the window to be viewed. Note that in this embodiment, the main display device 210 that displays the performance through the performance display window UD1 may be described as the main performance display unit 21.

The lower door mechanism DD has a main display window 4 located approximately in the center of its upper part, and a reel unit RU attached to the rear side of the main display window 4, on the inside of the cabinet G.

The reel unit RU is mainly composed of three reels: 3L (left reel), 3C (middle reel), and 3R (right reel). Each reel 3L, 3C, and 3R is composed of, for example, a cylindrical reel body and a translucent reel band attached to the periphery of the reel body, and multiple (e.g., 20) patterns are drawn on the reel band at a predetermined interval along the rotation direction of the reel. In addition, each reel 3L, 3C, and 3R is arranged in parallel (in a horizontal row) so that each can rotate vertically at a constant speed. The main display window 4 is, for example, configured as a transparent panel made of resin, and at least a part (e.g., three) of the patterns on the periphery of each reel 3L, 3C, and 3R can be seen. Additionally, light sources (reel lamps, which are included in the lamps and LEDs described below) are provided inside each of the reels 3L, 3C, and 3R at positions where the symbols can be seen at least through the main display window 4, and at least while each of the reels 3L, 3C, and 3R is spinning, they are illuminated from the inside with a constant brightness, ensuring the visibility of the symbols.

The lower door mechanism DD also has a sub-performance display unit 22 provided on the left side of the main display window 4, and a performance button 10b provided on the right side of the main display window 4. The sub-performance display unit 22 displays performance images displayed on the sub-display device 220 described below. The sub-performance display unit 22 can be configured as a touch panel, and can function not only as a performance display, but also as one of the performance buttons. The performance button 10b is an operation unit that accepts performance operations (performance operations) by the player.

The lower door mechanism DD has a roughly horizontal base formed below the main display window 4, and includes a MAX BET button 6a, a 1 BET button 6b, and a settlement button 9 on the left side, a performance button 10a located roughly in the center, and a medal slot 5 on the right side.

The MAX BET button 6a and the 1 BET button 6b are operation units that accept game operations (betting operations, which can also be called "insertion operations" or "betting operations") by the player to use medals deposited (credited) inside the pachislot machine 1. When the MAX BET button 6a is operated, if the current number of bets is less than the maximum number of bets (e.g., 3 medals) and the number of credited medals is equal to or greater than that difference, the maximum number of medals is bet. On the other hand, if the number of credited medals is less than that difference or more, no medals are bet. Also, when the 1 BET button 6b is operated, if the current number of bets is less than the maximum number of bets and there is one or more credited medals, one medal is bet.

The settlement button 9 is an operation unit that accepts the player's game operation (settlement operation) to return (settle) credited medals. If the settlement button 9 is operated when there are no credited medals, the player may be able to accept a game operation (C/P mode selection operation) to select either a credit mode (C mode) in which medals inserted or paid out are credited, or a pay mode (P mode) in which medals are not credited, within the creditable number (for example, 50 medals). In other words, the settlement button 9 can also function as a so-called C/P button. The performance button 10a is an operation unit that accepts the player's operation (performance operation) for performance.

The medal insertion slot 5 accepts medals inserted into the pachislot machine 1 from outside by a player. The accepted medals are detected by a selector 31, which will be described later, and it is determined whether or not they are valid medals. If a single accepted medal is not valid, the accepted medal is returned from a medal payout outlet 11, which will be described later. If a single accepted medal is valid and the current number of bets is less than the maximum number of bets, one medal is bet. If the current number of bets is the maximum number of bets 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 medal is returned from a medal payout outlet 11, which will be described later.

The lower door mechanism DD also has an information display device 14 provided between the main display window 4 and the above-mentioned base. The information display device 14 is configured to include multiple lamps (LEDs) and a 7-segment LED, and displays information related to the game depending on the lighting state of the lamps.

The lower door mechanism DD has a start lever 7 located on the left side below the base, three stop buttons 8L, 8C, 8R located approximately in the center, and a locking mechanism 15 located on the right side. The start lever 7 is attached so that it can be tilted freely within a predetermined angle range, and is an operation part that accepts a game operation (start operation) by the player to start a game. Each stop button 8L, 8C, 8R is provided corresponding to each reel 3L, 3C, 3R, and is an operation part that accepts a game operation (stop operation) by the player to stop the respective rotations.

The locking mechanism 15 is, for example, a key cylinder lock. When the lower door mechanism DD is closed, the manager of the amusement store (for example, a store clerk of the amusement store, etc.; the same applies below) inserts a door key (not shown) into the keyhole and turns it to the right to unlock the door, and the lower door mechanism DD is opened. The locking mechanism 15 may not only have the function of managing the opening and closing of the door mechanism, but also the function of a reset switch. For example, when the manager of the amusement store inserts the door key into the keyhole and turns it to the left, it may be possible to detect a reset operation similar to the reset switch 53 described below. In this embodiment, when the lower door mechanism DD is opened, the upper door mechanism UD can also be opened in conjunction with this, or a separate locking mechanism corresponding to the upper door mechanism UD can be provided so that the opening and closing can be managed independently.

The lower door mechanism DD also has a lower panel 13 located in the center of its lower part, a medal tray 12 located below the lower panel 13, a medal payout opening 11 located above the medal tray 12, and sound transmission holes 24a, 24b located on the left and right of the medal payout opening 11.

The lower back panel 13 is composed of a decorative panel on which model information such as a logo representing the model name and characters representing a motif are drawn, and a light source (lower back lamp included in the lamps and LEDs described below) for illuminating the decorative panel from the back side. The medal tray 12 stores medals paid out from the medal payout outlet 11. The medal payout outlet 11 discharges medals paid out (or returned) from inside the pachinko slot machine 1 to the outside. The medals discharged from the medal payout outlet 11 include those paid out from a hopper device 32 described below and those returned from a selector 31 described below through a cancel chute (not shown). The sound transmission holes 24a, 24b are on the rear side of each, and transmit sound such as sound effects and background music output from speakers 35a, 35b (speaker 35a is not referenced in FIG. 2) attached to the inside of the cabinet G toward the front side of the pachinko slot machine 1.

In this embodiment, the upper door mechanism UD and the lower door mechanism DD are provided in response to the interior of the cabinet G being divided into an upper space and a lower space, but as long as the opening in the cabinet G can be opened and closed appropriately, they can be configured as a single door mechanism or as three or more door mechanisms. They can also be configured as a double door mechanism in the front-to-rear direction (for example, an outer door and an inner door). The upper door mechanism UD and the lower door mechanism DD can be simply referred to as "doors" or "doors," or can be referred to as "opening and closing members," "door members," or "door members" because they function as members that can open and close the opening in the cabinet G.

[1-1-3. Variable display section]
As described above, the slot machine 1 includes the reels 3L, 3C, and 3R and the main display window 4. When the start lever 7 is operated (when the player performs a start operation), the stepping motors 51L, 51C, and 51R described below are driven and controlled to start the rotation of the reels 3L, 3C, and 3R. As a result, the symbols displayed in the main display window 4 are displayed variably. When the stop buttons 8L, 8C, and 8R are operated (when the player performs a stop operation), the stepping motors 51L, 51C, and 51R described below are driven and controlled to stop the rotation of the reels 3L, 3C, and 3R. As a result, the symbols displayed in the main display window 4 are displayed stationary.

In other words, each of the reels 3L, 3C, 3R and the main display window 4 constitutes a variable display section (means) capable of variably displaying (and stopping) multiple symbols in multiple rows, or multiple variable display sections (means) capable of variably displaying (and stopping) multiple symbols. The variable display section (means) can also be referred to as a "symbol display section (means)" or a "variable display section (means)". The symbols can also be referred to as "pictures" or "designs", and since they are information that can be visually identified by the player, they can also be referred to as "identification information" in that sense.

The main display window 4 is configured so that when the rotation of each reel 3L, 3C, 3R is stopped, three consecutively arranged symbols are displayed within its frame. That is, the main display window 4 displays one symbol (three in total) in each of the upper, middle, and lower areas of each column (the symbols are displayed in a 3 row x 3 column format within the frame of the main display window 4). The main display window 4 is sometimes referred to as the "symbol display area" or "window section", etc.

In addition, a winning line is defined in the main display window 4. The winning line is a line for determining whether or not a specified combination of symbols is displayed when the symbols in all columns are stopped and displayed in response to the player's stopping operation. In this sense, the winning line can also be called a "winning line" or a "determination line". The winning line is also configured as a line connecting any of the areas in each column. In other words, when the main display window 4 is configured to display symbols in a 3 row x 3 column format, a maximum of 27 winning lines can be defined. However, in practice, one or more of these lines can be defined as winning lines, and the remaining lines can be defined as inactive lines that are not winning lines.

For example, the line connecting the middle area of reel 3L, the middle area of reel 3C, and the middle area of reel 3R is called the "center line," the line connecting the upper area of reel 3L, the upper area of reel 3C, and the upper area of reel 3R is called 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 called the "bottom line," the line connecting the lower area of reel 3L, the middle area of reel 3C, and the upper area of reel 3R is called the "cross-up line," the line connecting the upper area of reel 3L, the middle area of reel 3C, and the lower area of reel 3R is called the "cross-down line," and so on. These are lines that connect the areas of each row in a straight line, so one or more of these lines are often defined as the active line. However, as mentioned above, so-called irregular lines that connect the areas of each row with broken lines can also be defined as the active line.

In order for the active lines to be activated, the player must bet the number of medals required for the current game (the number of medals that can be used to start the game) before starting the game. The number of active lines that are activated may be the same regardless of the number of bets, or may vary depending on the number of bets. For example, if the above-mentioned three lines, the "center line", "top line", and "bottom line", are defined as active lines, in the former case, the "center line", "top line", and "bottom line" are activated regardless of the number of bets, from 1 to 3. On the other hand, in the latter case, if the number of bets is 1, only the "center line" is activated, if the number of bets is 2, the "center line" and "top line" are activated, and if the number of bets is 3 (the maximum number of bets), the "center line", "top line", and "bottom line" are activated.

In this embodiment, the variable display unit has three reels 3L, 3C, and 3R, and a main display window 4 that can display three symbols in each column, and thus displays symbols in a 3 row x 3 column format, but the symbol display format in the variable display unit is not limited to this. For example, the number of reels can be one, two, or four or more, and the number of symbols displayed in each column can be one, two, or four or more, to display symbols in a format different from the above format. In this case, the number of effective lines that can be defined can also be increased or decreased as appropriate.

In addition, in this embodiment, the variable display unit displays the patterns by rotating each of the reels 3L, 3C, and 3R, but the configuration of the variable display unit 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 below, or it may be configured using other display devices (e.g., organic EL, 7-segment LED, etc.). It may also be configured using other physical devices (e.g., belts, etc.). The arrangement and size of the variable display unit can be changed as appropriate.

In addition, in this embodiment, the variable display unit functions as a main display unit directly related to the game, controlled by the main control circuit 100 described later. In addition, a variable display unit may be provided as a sub-display unit related to a performance not directly related to the game, controlled by the sub-control circuit 200 described later. The sub-display unit may be configured using, for example, the main display device 210 or the sub display device 220. In other words, not only the main display unit but also the sub-display unit may be provided as a variable display unit that displays a variable pattern in response to the player's start operation (or the establishment of other start conditions) and stops the pattern in response to the player's stop operation (or the establishment of other stop conditions). In this case, in order to enable the player to identify whether the variable display unit is directly related to the game or not, an identification display with characters such as "reel" or "main reel" may be attached near the main display unit, so that the variable display unit can be identified as the main display unit. Such 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 slot machine 1 includes a medal insertion slot 5 that accepts medals inserted into the slot machine 1 by a player from outside. The medal insertion slot 5 and a selector 31 described below 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, and such an insertion operation can be rephrased as a betting operation, for example. Therefore, the medal insertion slot 5 can be said to be a betting operation detection unit (means) that can detect the betting operation of the player. The shape, arrangement, size, etc. of the medal insertion slot can be changed as appropriate. In addition, when the slot machine 1 is configured as a medal-less gaming machine described below, the medal insertion slot is not necessarily a required configuration.

In this embodiment, the use of medals as gaming media as gaming value used in games or awarded according to game results is described as an example, but the gaming value used in this manner is not limited to this. For example, coins, gaming balls, gaming point data or tokens, etc. can also be used. Furthermore, gaming value can also be simply referred to as "value" or "game value", etc.

[1-1-5. Operation section]
The pachislot machine 1 is provided with, for example, the following operation units as operation units that can be operated by a player. Note that the following operation units are merely examples, and a configuration having operation units different from these may be used. Alternatively, among these, the operation units that are not necessarily required may not be provided.

[1-1-5-1. Bet button]
As described above, the slot machine 1 includes the MAX bet button 6a and the 1 bet button 6b that accept the player's betting operation to use the medals deposited (credited) therein. In addition, such betting operation is detected by the bet switch 6S 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 betting operation. Note that the bet button only needs to be able to detect the player's betting operation, and its shape, arrangement, size, etc. can be changed as appropriate. In addition, in this embodiment, the MAX bet button 6a and the 1 bet button 6b are provided, but it is also possible to provide only the MAX bet button 6a without providing the 1 bet button 6b. In addition, it is also possible to provide a separate 2 bet button for betting two medals.

[1-1-5-2. Start lever]
As described above, the pachislot machine 1 is equipped with the start lever 7 that accepts a start operation by the player to start a game. This 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 unit (means) that can detect the start operation by the player. Note that the start lever only needs to be capable of detecting the start operation by the player, and its shape, position, size, etc. can be changed as appropriate.

[1-1-5-3. Stop button]
As described above, the pachislot machine 1 is provided with stop buttons 8L, 8C, and 8R that are provided corresponding to the reels 3L, 3C, and 3R and accept the player's stop operation to stop the respective reels. In addition, such a start operation is detected by a stop switch 8S described below. Therefore, the stop buttons 8L, 8C, and 8R and the stop switch 8S constitute a stop operation detection unit (means) that can detect the player's stop operation. Note that the stop buttons only need to be capable of detecting the player's stop operation, and their shape, arrangement, size, and the like can be changed as appropriate.

[1-1-5-4. Settlement button]
As described above, the pachislot machine 1 is equipped with a settlement button 9 that accepts a settlement operation (return operation) by the player to return (settle) credited medals. In addition, such a settlement operation is detected by a settlement switch 9S described below. Therefore, the settlement button 9 and the settlement switch 9S constitute a settlement operation detection unit (means) that can detect the settlement operation of the player. Note that the settlement button only needs to be capable of detecting the settlement operation of the player, and its shape, arrangement, size, etc. can be changed as appropriate.

[1-1-5-5. Performance buttons]
As described above, the slot machine 1 includes buttons 10a and 10b for effecting a game that accepts the player's effect operation. Such effect operation is detected by a detection switch (not shown) provided corresponding to each of the buttons for effecting a game. Therefore, the buttons 10a and 10b for effecting a game and the detection switch constitute an effect operation detection unit (means) capable of detecting the effect operation of the player. The effect button only needs to be capable of detecting the effect operation of the player, and its shape, arrangement, size, etc. can be changed as appropriate. In addition, in this embodiment, two effect buttons 10a and 10b are provided, but it is possible to configure the machine without providing either of these buttons, or to configure the machine with only one of these buttons. It is also possible to configure the machine with three or more effect buttons.

The main uses of the performance buttons are to change the performance mode when a specific performance (for example, an operation-linked performance described below) is executed, and to perform selection and confirmation operations in a user menu described below. Therefore, it is possible to configure the system so that performance buttons are provided according to the purpose. For example, the performance buttons 10a and 10b are used for the former purpose, and the above-mentioned touch panel can be used for the latter purpose. For the latter purpose, it is also possible to configure the system so that a jog dial, cross key, or the like capable of receiving selection and confirmation operations is provided as a separate performance button.

[1-1-6. Medal payout outlet]
As described above, the pachislot machine 1 is equipped with a medal payout outlet 11 that discharges medals that are paid out (or returned) from inside the pachislot machine 1 to the outside. When a winning prize is won and medals are paid out, the medal payout outlet 11 awards the medals paid out from a hopper device 32 (described below) to the player, and can therefore be said to be part of a bonus awarding means that awards a bonus to the player. The shape, arrangement, size, etc. of the medal payout outlet can be changed as appropriate. Furthermore, when the pachislot machine 1 is configured as a medal-less gaming machine (described below), the medal payout outlet is not necessarily a required component.

[1-1-7. Medal tray]
As described above, the pachislot machine 1 is equipped with a medal tray 12 that stores medals paid out from the medal payout opening 11. In other words, the medal tray 12 constitutes a storage section (means) capable of storing the granted game value. Note that the shape, arrangement, size, etc. of the medal tray can be changed as appropriate. Also, when the pachislot machine 1 is configured as a medal-less gaming machine described below, this is not necessarily a required component.

[1-1-8. Waist panel]
As described above, the slot machine 1 is equipped with a lower back panel 13, which is composed of a decorative panel on which model information is drawn, and a lower back lamp for illuminating the decorative panel from the rear side. The lower back panel 13 is basically intended to clearly show the player what model the slot machine 1 is, but it can also be configured as one of the performance execution means capable of executing a performance, for example, by the lighting state of the lower back lamp, or by configuring the lower back panel 13 itself as an image display device, etc.

[1-1-9. Information display section]
As described above, the pachislot machine 1 includes the information display device 14 that displays information about the game by its lighting state. That is, the information display device 14 constitutes an information display unit (means) that can display information about the game. .

The information display device 14 is configured to include, for example, an insert lamp, a start lamp, a replay lamp, a bet number lamp, a credit lamp, a payout number lamp, an indication monitor, a limit lamp, and the like.

The insert lamp lights up to indicate that medals can be inserted. The start lamp lights up to indicate that play can be started by operating the start lever 7. The replay lamp lights up to indicate that medals have been automatically inserted as a result of the replay operation. The bet number lamp lights up to indicate the number of medals bet. The credit lamp indicates the number of medals credited depending on how it lights up. The payout number lamp indicates the number of medals paid out (payout number) depending on the game result depending on how it lights up.

The instruction monitor is also configured to include a notification lamp (stop operation display section) and a section lamp (state display section). The notification lamp displays information on the stop operation by lighting in a manner that uniquely corresponds to the information on the stop operation to be notified in a situation where information on the stop operation is notified to the player (for example, in an AT state). Note that "a manner that uniquely corresponds to the information on the stop operation to be notified" refers to, for example, a manner in which the number "1" is displayed on the instruction monitor when notifying the push order (which may be described as "hitting order" in this embodiment) "1st (performing the first stop operation on reel 3L)", the number "2" is displayed on the instruction monitor when notifying the push order "2nd (performing the first stop operation on reel 3C)", and the number "3" is displayed on the instruction monitor when notifying the push order "3rd (performing the first stop operation on reel 3R)". 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 about the stop operation may be displayed using either the credit lamp or the payout number lamp.

In this way, in this embodiment, in a situation where information on a stop operation is notified to a player, not only the sub-side notification means (for example, the main performance display unit 21) controlled by the sub-control circuit 200 described later, but also the instruction monitor as the main-side notification means controlled by the main control circuit 100 described later, not only notifies the information on the stop operation, but also notifies the information on the main side notification means in a manner different from that of the sub-side notification means. In other words, 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 notify the information on the stop operation directly. For example, when notifying the push order "1st", even if the number "1" is displayed on the instruction monitor, some players may not be able to identify the content of the notification. On the other hand, the sub-side notification means only needs to directly notify the information on the stop operation. For example, when notifying the push order "1st", the main performance display unit 21 only needs to directly notify the instruction information for performing the first stop operation on the reel 3L.

In addition, the section lamp, when lit, indicates that the current state is in the advantageous section, which will be described later. For example, when transitioning from a non-advantageous section to an advantageous section, which will be described later, the section lamp lights up at any timing before play in the advantageous section starts, and when the advantageous section ends and transitions to a non-advantageous section, the lamp goes out at any timing before play in the non-advantageous section starts. Note that the timing of lighting the section lamp is not limited to this. For example, when transitioning from a performance section (normal advantageous section) in a non-advantageous section or advantageous section to an increase section (AT state) in an advantageous section, which will be described later, for the first time, the lamp may light up at any timing before play in the increase section starts. In other words, the section lamp may indicate that the section is in an advantageous section, regardless of whether it is a performance section or an increase section, or may indicate at least the period from the start of the first increase section to the end of the advantageous section, including this.

The limit lamp also indicates, depending on the lighting state, whether or not a limit process described below has been executed. For example, by lighting up when a limit process has been executed, it notifies the player that a favorable state (e.g., AT state) has been forcibly ended by the execution of the limit process. Also, by flashing when the execution of the limit process is imminent, it notifies the player that there is a high possibility that the favorable state will be forcibly ended by the execution of the limit process. In addition to these, by providing triggers for lighting, flashing, or going off, it is also possible to appropriately notify other information regarding the limit process.

[1-1-10. Production display section]
As described above, the slot machine 1 includes a main effect display unit 21 and a sub effect display unit 22 that display effect images. The main effect display unit 21 and the sub effect display unit 22 are capable of displaying effect images. The display unit (means) is also configured as one of the presentation execution means capable of presenting a presentation to the player from a visual perspective.

The main display unit 21 includes a main display device 210 that displays effects through a display window UD1. The main display device 210 is configured as a so-called projection mapping device having 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 a screen device C that makes an image appear by irradiating the irradiation light from the irradiation unit B. In this embodiment, the main display device 210 is configured in this way to enable advanced and powerful performance display, but the configuration of the main display device 210 is not limited to this. In other words, it is sufficient to be able to perform a performance from a visual perspective for the player, and it can be configured as an image display device such as a liquid crystal display device or an organic EL, or a display device such as a 7-segment LED, or it can be configured as a variable display device such as a sub reel or a dot display device. In addition, from such a perspective, the shape, arrangement, size, etc. can be appropriately changed. Also, if the pachislot machine 1 is a game that is primarily entertaining based on the results of the winning combination, for example, it can be configured not to have a main performance display unit 21 (the same goes for the sub performance display unit 22).

The sub-performance display unit 22 includes a sub-display unit 220. The sub-display unit 220 is configured as a liquid crystal display unit. The sub-display unit 220 can be configured as another image display unit or display unit, as with the main display unit 210, and can also be configured as a variable display unit or a dot display unit. From this perspective, the shape, arrangement, size, and the like can be changed as appropriate. The main performance display unit 21 is configured as a large screen, so it mainly displays performances closely related to the current game, such as push order notifications, winning notifications, or continuous performances, while the sub-performance display unit 22 is configured as a small screen, so it is possible to display the display contents separately according to the purpose, such as mainly displaying performances that are not so closely related to the current game, such as game history. In this embodiment, the main performance display unit 21 and the sub-performance display unit 22 are configured to have two performance display units, but it is possible to configure the system without providing either of them, or to configure the system to have only one of them. It is also possible to configure the system to have three or more performance display units.

[1-1-11. Lamp]
As described above, the slot machine 1 is equipped with one or more lamps (light-emitting means) that can perform effects by their light-emitting modes (including not only lighting, blinking, or extinguishing, but also the brightness and light-emitting color when configured as a full-color LED), such as the upper lamp 23 given as an example. Furthermore, such light-emitting means is configured as one of the effect execution means that can perform effects from a visual perspective for the player. From this perspective, the number, shape, arrangement, size, etc., of the light-emitting means can be appropriately changed.

Other lamps included in the lamps and LEDs described below include, for example, side lamps provided on both end faces of the upper door mechanism UD and the lower door mechanism DD, and operation unit lamps provided within each operation unit. The latter include a function to inform the player whether or not each operation unit can be operated, so when this function is exercised, the light emission pattern does not change depending on the performance content, but can be controlled to emit light in a unique light emission pattern.

[1-1-12. Speaker]
As described above, the slot machine 1 includes speakers 35a and 35b that output sound effects, background music, and the like. The speakers 35a and 35b constitute a sound output means capable of performing effects by outputting sound. They are also configured as one of the performance execution means capable of performing performances from an auditory perspective for the player. From this perspective, the number, shape, arrangement, size, and the like of the speakers can be changed as appropriate.

[1-1-13. Other production devices]
In addition, in the pachislot machine 1, it is also possible to provide a performance device other than the various performance devices (performance execution means) described above. For example, it is also possible to provide a performance device such as a movable performance device, a vibration performance device that performs a performance by vibration, or an air performance device that performs a performance by injecting air, and perform a performance. In other words, any of the performance devices that can perform a performance that can appeal to any of the five senses of the player (sight, hearing, touch, taste, smell) (allowing the player to recognize that a performance is being performed) can be used. Therefore, in this embodiment, "performing a performance" indicates that a performance may be performed using any one or more of the various performance devices (performance execution means) described above, unless otherwise specified.

[1-2. Internal structure]
[1-2-1. Selector]
The selector 31 (reference numeral omitted in FIG. 2) is a passage through which medals inserted through the medal insertion slot 5 flow down, and is provided on the rear side of the lower door mechanism DD. The selector 31 may be, for example, a medal sensor (described later). 31S and a sorting device.

The medal sensor 31S detects medals inserted through the medal insertion port 5 and determines whether the detected medals are appropriate medals. If the medal sensor 31S determines that the detected medals are appropriate medals and the medals are in a state where they can be accepted, the sorting device is controlled to guide the medals to the hopper device 32 side described below. In this case, the bet number or credit number is incremented by 1. On the other hand, if the medal sensor 31S determines that the detected medals are not appropriate medals and the medals are not in a state where they can be accepted, the sorting device is controlled to return the medals through the cancel chute and from the medal payout outlet 11. If an abnormality occurs in the detection of medals by the medal sensor 31S, a selector error occurs. In this case, the error state is cleared by performing a reset operation after eliminating the cause of the abnormality (for example, a medal jam).

In other words, the selector 31 constitutes a gaming medium detection unit (means) capable of detecting the inserted gaming medium. The selector 31 also constitutes a determination means capable of determining whether the inserted gaming medium is proper or not. The selector 31 also constitutes a sorting means that stores the inserted gaming medium internally if it is proper, and discharges it to the outside if it is not proper. The configuration, arrangement, size, etc. of the selector 31 can be changed as appropriate. Furthermore, when the pachislot machine 1 is configured as a medal-less gaming machine described below, the selector 31 is not necessarily a required configuration.

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

The bucket is configured to be able to store a certain number of medals. Any medals exceeding this number are guided through a guide passage provided on the top side to the auxiliary medal storage 33 (described below). If the medals stored in the bucket become empty, a hopper empty error occurs. In this case, the error state is cleared by refilling the bucket with medals and performing a reset operation.

The disk unit has multiple medal-shaped cutouts formed radially from the center, and the central shaft is rotated in response to a drive signal to guide medals that fit into the cutouts one by one to the discharge unit. The medals stored in the bucket unit are stirred up as the disk unit rotates. If an abnormality occurs in the rotation of the disk unit, a hopper jam error occurs. In this case, the error state is cleared by performing a reset operation after eliminating the cause of the abnormality (for example, a medal jam).

The count sensor detects the medals discharged from the discharge section and counts the number of medals. For example, when one medal is to be paid out, the disk section starts to rotate, and then the disk section stops rotating when the count sensor counts that one medal has been paid out. In this way, the correct number of medals is paid out.

In other words, the hopper device 32 constitutes a gaming media payout section (means) capable of paying out gaming media. Also, as described above, it can be said to be part of a bonus granting means for granting bonuses to players. Also, the configuration, arrangement, size, etc. of the hopper device 32 can be changed as appropriate. Also, if the pachislot machine 1 is configured as a medal-less gaming machine, which will be described later, it is not necessarily a required configuration.

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

The storage section is configured to be able to store a certain number of medals. If the auxiliary medal storage switch 33S determines that more than the certain number of medals have been stored, an auxiliary medal storage error occurs. In this case, the error state is released if the medals stored in the storage section are reduced to at least below the certain number and a reset operation is performed.

In other words, the auxiliary medal storage 33 constitutes a surplus gaming media storage section (means) capable of storing surplus gaming media. Note that the configuration, arrangement, size, etc., of the auxiliary medal storage 33 can be changed as appropriate. Also, if the pachislot machine 1 is configured as a medal-less gaming machine described below, this is not necessarily a required configuration.

[1-2-4. Power Supply
The power supply device 34 is provided in a lower space within the cabinet G. The power supply device 34 has, for example, a power supply board 34a and a power switch 34b. When the power switch 34b is turned on, The power supply device 34 supplies power to the slot machine 1. The power supply device 34 converts the AC voltage of 100V supplied from a power cable (not shown) into the DC voltage required by each part, just like household electrical appliances. The power supply device 34 converts the converted power into electric power and supplies the converted power to each unit. In other words, the power supply device 34 constitutes a power supply unit (means) capable of supplying the necessary power to the gaming machine. can be changed as appropriate.

In this embodiment, the setting key switch 52 and reset switch 53 described below are configured to be provided on the main control board 71 (more specifically, on the main control board case described below), but these switches can also be configured to be provided on the power supply 34.

[1-2-5. Substrate]
The slot machine 1 includes the following boards as boards necessary for various controls. Note that the boards listed below are merely examples, and the slot machine 1 may include boards different from these boards, and may not include boards that are not essential.

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

The specifications of the main control board 71 are subject to various constraints, and although it is basically configured with various electronic components DIP mounted, some or all of the various electronic components may be SMT mounted (surface mounted). In this case, test points may be provided to check operation using a tester or oscilloscope. Small electronic components not exceeding 6 mm square may be used for some or all of the various electronic components. The board surface of the main control board 71 may also be configured with multiple layers.

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

[1-2-5-3. Other substrates]
(Main relay board)
The main relay board 73 (reference numeral omitted in FIG. 2) is attached to a specific position (for example, the rear side of the lower door mechanism DD) in the cabinet G, and is an intermediate control board for relaying between the main control board 71 and various devices connected to the main relay board 73, and between the main control board 71 and the sub-control board 72. Since the main relay board 73 is configured as a board separate from the main control board 71 for convenience of control efficiency and wiring efficiency, it is also possible to provide all the functions of the main relay board 73 to the main control board 71 and not provide the main relay board 73 unless there is a particular problem. From this viewpoint, 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 (for example, the rear side of the lower door mechanism DD) in the cabinet G, and is an intermediate control board for relaying between the sub-control board 72 and various devices connected to the sub-relay board 74, and between the main control board 71 and the sub-control board 72. Since the sub-relay board 74 is configured as a board separate from the sub-control board 72 for the convenience of control efficiency and wiring efficiency, it is also possible to configure the sub-relay board 74 without providing the sub-relay board 74, by giving all the functions of the sub-control board 72, unless there is a particular problem. From this viewpoint, the sub-relay board 74 may be further divided into a plurality of relay boards to improve control efficiency and wiring efficiency. In other words, a plurality of boards may be provided as the sub-relay board.

(External common terminal board)
The external centralized terminal board 55 is attached to a specific position (e.g., the back side of the lower space) in the cabinet G, and outputs signals such as a medal insertion signal, a medal payout signal, external signals 1 to 4, and a security signal to the outside of the slot machine 1. The external signals 1 to 4 can be set to have appropriate output start and end conditions, making it possible to notify the outside of the transition of the internal state of the slot machine 1 (e.g., bonus state or AT state) according to the game characteristics. The external centralized terminal board 55 is usually connected to an external data display device or hall computer, so that these devices can recognize not only the medal insertion/payout status and error occurrence status in the slot machine 1, but also the transition status of such internal states.

(Test machine interface board)
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 (test firing test) of the Pachislot machine 1 (note that these relay boards are not installed in the Pachislot machine 1 as a released product for sale, so the main control board 71 for sale does not have various electronic components required for connecting to the first interface board 301 for the test machine and the second interface board 302 for the test machine.). For example, test signals for controlling 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 test signals related to the push order navigation determined by the main control board 71 are output via the second interface board 302 for the test machine.

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

As described above, the pachislot machine 1 has 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 and the main relay board 73, the main relay board 73 and the sub-relay board 74, and the sub-relay board 74 and the sub-control board 72 are electrically connected to each other. Furthermore, the main control board 71 and the sub-control board 72 are electrically connected to each other so that one-way serial communication is possible from the main control board 71 to the sub-control board 72 via the main relay board 73 and the sub-relay board 74.

The main control board 71 is equipped with a main control circuit 100 as a game control unit that controls the game. The main control circuit 100 is composed of, for example, a main CPU 101, a main ROM 102, a main RAM 103, a clock pulse generating circuit (not shown), a random number circuit (not shown), etc. The main ROM 102 stores various control programs executed by the main CPU 101, various data tables, data for sending various control commands (commands) to the sub-control circuit 200, etc. The main RAM 103 is provided with a storage area for storing various data such as internal winning combinations determined by the execution of the control programs. The clock pulse generating 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 signal. In addition, one or more values are extracted as random numbers from the generated random numbers as necessary. In this way, all game actions are controlled.

The sub-control board 72 is equipped with a sub-control circuit 200 as a performance control unit that controls performance. The sub-control circuit 200 is configured to include, for example, a sub-CPU 201, a sub-RAM 203, etc. In addition, a ROM cartridge board 202 is connected to the sub-control board 72. The ROM cartridge board 202 stores various control programs executed by the sub-CPU 201, various data tables, and various performance data (for example, video data and drive data related to the main display device 210, video data related to the sub-display device 220, lamp data related to the lamp/LED group, sound data related to the speaker group, etc.). The sub-RAM 203 is provided with a storage area for registering the performance content and various performance data determined by the execution of the control program, and a storage area for storing data related to various control commands (commands) transmitted from the main control board 71. The random numbers for the effects may be generated and extracted within the sub-CPU 201 from a predetermined range of random numbers (e.g., 0 to 32767, etc.), or may be generated and extracted by providing a random number circuit similar to the main control circuit 100. Also, instead of the ROM cartridge board 202, a sub-ROM may be included within the sub-control circuit 200, and various control programs and the like may be stored in the sub-ROM. Also, various performance data may be stored in the ROM cartridge board 202, and various control programs and various data tables may be stored in the sub-ROM within the sub-control circuit 200. Also, the sub-control circuit 200 may be configured to include a microprocessor dedicated to images such as a GPU (e.g., also called a "VDP"), which may be used to generate (edit) images to be displayed on the main display device 210 and the sub-display device 220.

The stepping motors 51L, 51C, 51R, the key switch 52 for setting, the reset switch 53, the role ratio monitor device 54, the external central terminal board 55, the hopper device 32, the auxiliary medal storage switch 33S, and the power supply device 34 are electrically connected to the main control board 71. The door opening/closing monitor switch 56, the medal sensor 31S, the bet switch 6S, the start switch 7S, the stop switch 8S, the settlement switch 9S, and the information display device 14 are also electrically connected to the main control board 71 via the main relay board 73. If the first interface board 301 for the test machine and the second interface board 302 for the test machine are mounted, they are electrically connected to the main control board 71 via the main relay board 73, for example.

Note that the external centralized terminal board 55, hopper device 32, auxiliary medal storage switch 33S, power supply device 34, medal sensor 31S, bet switch 6S, start switch 7S, stop switch 8S, settlement switch 9S, information display device 14, first test machine interface board 301, and second test machine interface board 302 have already been explained, so explanations will be omitted here.

Each stepping motor 51L, 51C, 51R is connected to each reel 3L, 3C, 3R via a gear with a predetermined reduction ratio, and the driving of the stepping motors 51L, 51C, 51R rotates each reel 3L, 3C, 3R at a certain angle. Therefore, the main CPU 101 counts the number of times a pulse is output to each stepping motor 51L, 51C, 51R, and manages the symbol positions of each reel 3L, 3C, 3R based on the count results. Each reel 3L, 3C, 3R is provided with 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.

The setting key switch 52 is used when changing the setting value of the slot machine 1 (for example, 6 levels of setting 1 to setting 6) (setting change) or when checking the setting of the slot machine 1 (setting check). Here, the setting value indicates the degree of advantage of the player in the game, and usually, the lower the setting value (for example, closer to setting 1), the lower the degree of advantage of the player, and the higher the setting value (for example, closer to setting 6), the higher the degree of advantage of the player. The setting key switch 52 is turned on when, for example, an administrator of the gaming establishment inserts a setting key (not shown) into the keyhole and turns it counterclockwise from the initial position, and turned off when it is returned to the initial position from the counterclockwise position. Note that when the power supply of the slot machine 1 is off, the setting can be changed by turning the setting key switch 52 on and then turning the power supply on, and the setting can be checked by turning the setting key switch 52 on while the power supply of the slot machine 1 is on.

The reset switch 53 can detect a reset operation by the manager of the gaming establishment. The reset operation is an operation for releasing various error states. The reset switch 53 can also detect a setting value determination operation by the manager of the gaming establishment when the setting can be changed. When the reset switch 53 is operated when the setting can be changed, the setting value increases by one each time it is operated (when it reaches setting 6, it returns to setting 1). In this way, the setting value determination operation can be performed. The setting value determined in this way is confirmed when the start lever 7 is operated once thereafter. In other words, the start switch 7S can detect a setting value confirmation operation by the manager of the gaming establishment. In this way, when changing the setting, a setting change operation is required, such as turning on the setting key switch 52, operating the reset switch 53 to select a setting value, operating the start lever 7 to confirm the selected setting value, and then turning off the setting key switch 52. This is one example of a setting change operation, and the setting can also be changed by other operations. Also, when changing or checking settings, the current setting value may be displayed, for example, on the credit lamp or payout number lamp mentioned above.

The role ratio monitor device 54 is, for example, composed of a 4-digit 7-segment LED and is provided inside the main control board case. The role ratio monitor device 54 sequentially displays various ratio information related to the game that is tallied and calculated by the main CPU 101. These ratio information are used when the manager of the gaming facility checks whether the pachislot machine 1 has been tampered with. 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 may also be provided in another location within the cabinet G. For example, it may be provided on the main control board case. In addition, a management switch for starting the display on the role ratio monitor device 54 or for switching the contents thereof may be provided in the cabinet G, and when this is operated, the above-mentioned various ratio information may be displayed. In addition, assuming that such a management switch is used, for example, the information display device 14 may be used in combination with the role ratio monitor device 54. Also, immediately after power is turned on or after a predetermined time has elapsed since power is turned on (for example, about 10 seconds; a buffer time that takes into account the time required for the main control circuit 100 and the sub-control circuit 200 to start up), in order to be able to confirm that the 4-digit 7-segment LED of the role ratio monitor device 54 is functioning normally, it is desirable to configure it so that it lights up (or blinks) for a predetermined period of time with a test pattern such as "8.8." (a pattern in which all segment and decimal LEDs are lit).

In the role ratio monitor device 54, for example, the top two digits display the type of the ratio information, and the bottom two digits display a value (%) indicating the ratio information. Here, the various ratio information displayed on the role ratio monitor device 54 includes, for example, cumulative specific section ratio information, consecutive role ratio information and role ratio information for the most recent 6000 games, cumulative consecutive role ratio information and role ratio information, etc.

The specific section ratio information is information that indicates the ratio of the number of plays in a play section (for example, AT state) in which information on a stop operation advantageous to the player was notified (or it may simply be the number of plays in an advantageous section) among the play sections of the target number of plays (for example, 175,000 games for "cumulative", 6,000 games for "last 6,000 games", the same below). In addition, the continuous feature ratio information is information that indicates the ratio of the number of medals paid out during the operation of the first type special feature (RB) (including the operation of the first type special feature (RB) when the feature continuous operation device (BB) related to the first type special feature is in operation) among the number of medals paid out in the play section of the target number of plays. The feature ratio information is information that indicates the ratio of the number of medals paid out during the operation of the first type special feature (RB), the second type special feature (CB), and the normal feature (SB) to the number of medals paid out in the play section of the target number of plays. Here, the operation of the first type special feature (RB) includes the operation of the first type special feature (RB) when the feature continuous operation device (BB) related to the first type special feature is in operation, and the operation of the second type special feature (CB) includes the operation of the second type special feature (CB) when the feature continuous operation device (MB) related to the second type special feature is in operation.

In addition, the game section (for example, AT state) in which the information on the stop operation advantageous to the player was notified can be regarded as the operation of the role or the operation of the role continuous operation device, and can be the subject of aggregation and calculation in the respective ratio information. In other words, the role ratio monitor device 54 is sufficient as long as it appropriately displays the necessary ratio information, and the various ratio information that can be displayed is not limited to these. In addition, for example, in the case of displaying continuous role ratio information in a model that does not have a first-class special role (RB), or in the case of displaying specific section ratio information in a model that does not have an advantageous section function (AT function), in a model in which the corresponding numerical information (corresponding information) does not exist, when the corresponding item is displayed, it is desirable to display a non-corresponding information identification display such as lighting two vertical bars in the center, for example, "- -", in the last two digits of the 7-segment LED that displays the numerical information (% information indicating the ratio) of the 4-digit 7-segment LED, so that the person checking can recognize at a glance that the corresponding information does not exist.

The door open/close monitoring switch 56 is provided, for example, on the opening/closing side (right side) of the lower door mechanism DD. It may be provided on the rear side of the lower door mechanism DD, or on the cabinet G side. A similar door open/close monitoring switch may also be provided on the upper door mechanism UD. The door open/close monitoring switch 56 monitors the opening/closing of the lower door mechanism DD by turning on when the lower door mechanism DD is in an open state and turning off when the lower door mechanism DD is in a closed state. When the door open/close monitoring switch 56 turns on, a door open error occurs. In this case, the error state is released when the lower door mechanism DD is closed.

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

Note that the ROM cartridge board 202, main display device 210, sub-display device 220, performance buttons, lamps/LEDs, and speakers have already been explained, so explanations will be omitted here.

The 24-hour door monitoring unit 61 is installed, for example, on the opening/closing side (right side) of the lower door mechanism DD, in the same way as the door opening/closing monitoring switch 56. 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 making it possible for such monitoring to be performed on the sub-control circuit 200 side, it is also possible to store the opening/closing history of the lower door mechanism DD for a certain period of time. This opening/closing history can be confirmed from the hall menu, which will be described later. Therefore, for example, if there is a history of the door being opened after the arcade manager has left outside of business hours, or if there is a history of the door being opened for a long period of time during business hours, it is possible to recognize that there is a high possibility that fraudulent activity has occurred.

[3. Functional flow of the Pachislot machine]
Next, a functional flow of the slot machine 1 will be described with reference to Fig. 4. Fig. 4 is a diagram for explaining a functional flow of the slot machine 1.

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

The internal lottery means (main CPU 101 that performs the internal lottery process described later) performs a lottery based on the extracted random number value and determines the internal winning combination. The internal winning combination determines in advance the combination of symbols that are permitted to be displayed on the pay line. The types of combinations of symbols include those related to "winning" that give the player benefits such as the payout of medals, the operation of replay, and the operation of bonuses, and those related to other so-called "losing" combinations. The combination related to the payout of medals is called a "small combination", the combination related to the operation of replay is called a "replay combination", and the combination related to the operation of a bonus (bonus state) is called a "bonus combination". The combination that can be an internal winning combination (i.e., the combination of symbols that is permitted to be established) is sometimes simply called a "combination". The internal winning combination is sometimes called a "winning combination", a "predetermined result", or a "derivation allowable condition". The internal lottery means may also be referred to as a "role determining means," "winning role determining means," "pre-determination means," or "derivation allowable condition determining means."

When the start lever 7 is operated (a start operation is performed), the reels are rotated. After that, when the player operates the stop buttons (respective stop buttons 8L, 8C, 8R) corresponding to the reels (respective reels 3L, 3C, 3R) (a stop operation is performed), the reel stop control means (main CPU 101 which performs the reel stop control process described later) controls the rotation of the corresponding reel to stop based on the internal winning combination and the timing (or the order in which the stop buttons are pressed) when the stop buttons are pressed. Note that the operation means for performing the start operation is not limited to a lever-shaped one like the start lever 7, and may be any operation means as long as the player can perform the start operation. Also, the operation means for performing the stop operation is not limited to a button-shaped one like the respective stop buttons 8L, 8C, 8R, and may be any operation means as long as the player can perform the stop operation.

In the pachislot machine 1, basically, control is 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 reel rotates within this specified time is called the "number of sliding pieces." In this embodiment, when the specified period is 190 msec, the maximum number of sliding pieces (maximum number of sliding pieces) is set to four symbols.

When an internal winning role that allows the display of a winning symbol combination has been determined, the reel stop control means stops the rotation of the reels within a specified time of usually 190 msec (four symbols) so that the symbol combination is displayed on the winning line as much as possible. The reel stop control means also uses the specified time to stop the rotation of the reels so that symbol combinations not permitted to be displayed by the internal winning role are not displayed on the winning line. The symbols displayed when the reels stop spinning are sometimes referred to as "stop display" or "display result". The display of symbols when the reels stop spinning is sometimes referred to as "deriving the stop display" or "deriving the display result".

The reel stop control means may also be configured to perform automatic stop control to automatically stop each reel when a predetermined automatic stop time has elapsed since the reels started spinning, even if the player has not performed a stop operation. In this case, since the reels will stop without the player's stopping operation, it is desirable to stop the spinning of the reels so that no winning symbol combinations are displayed along the pay line, even if any internal winning combination has been determined.

In this way, when all of the rotations of the multiple reels are stopped, the winning determination means (main CPU 101 which performs the winning operation determination process described below) determines whether the combination of patterns displayed on the pay line is related to a winning combination (or is other predetermined combination).
That is, a determination is made as to whether or not a winning symbol combination (or other predetermined symbol combination) has been achieved. Then, when the winning determination means determines that the displayed symbol combination is a winning symbol (or other predetermined one) (i.e., a winning symbol combination (or other predetermined symbol combination) has been achieved), a bonus such as a payout of medals is given to the player, or various controls are carried out in response to this. In the pachislot machine 1, as an example, the above series of steps is carried out as one game (unit game).

The winning determination means may simply determine whether the combination of symbols displayed on the pay line corresponds to any of a plurality of predetermined combinations of symbols, or may determine whether the combination corresponds to a combination of symbols related to an internal lottery role determined by the internal lottery means. In other words, in the former case, it may determine whether the combination of symbols related to a winning role is separate from the internal lottery role. In this case, as long as the reel stop control means appropriately controls the reels to stop, the prevention of erroneous winning can be sufficiently guaranteed, and the control burden related to erroneous winning detection can be reduced. On the other hand, in the latter case, by making it possible to determine whether the combination of symbols related to a winning role is a combination of symbols that was permitted to win, if an erroneous winning occurs due to a reel malfunction, the erroneous winning can be detected, and security can be improved.

In addition, in pachislots, during the sequence of game operations described above, various effects are produced using the display devices (e.g., main display device 210, sub display device 220, etc.), the light output from various lamps (e.g., upper lamp 23, etc.), the sound output from speakers (e.g., speakers 35a, 35b, etc.), or a combination of these. In other words, these are effect execution means that execute the effects. The content of the effect executed by the effect execution means may be determined on the main control circuit 100 side (main side) or on the sub control circuit 200 side (sub side). In other words, any of these can be effect content determination means.

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

Next, when the presentation content is determined by the presentation content determination means, the presentation execution means executes the corresponding presentation in conjunction with each trigger, such as when the reels start to spin, when each reel stops spinning, and when it is determined whether or not a prize has been won. In this way, in the pachislot machine 1, for example, by executing presentation content associated with an internal winning role, the player is provided with an opportunity to know or predict the determined internal winning role (which can also be expressed as the combination of symbols to aim for or the order in which buttons should be pressed, etc.), thereby increasing the player's interest.

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

[4-1. Design arrangement]
As described above, the pachislot machine 1 is designed to perform a game by displaying a plurality of symbols in a variable and stationary manner. Therefore, the main control circuit 100 must be configured to be able to grasp which symbols are located at which positions on each of the reels 3L, 3C, and 3R. For this reason, the main ROM 102 stores data for identifying the types of symbols at each symbol position on at least each of the reels 3L, 3C, and 3R. As long as such a purpose is achieved, the data configuration can adopt various configurations, and in this embodiment, a symbol arrangement table (see FIG. 9) described later is used as an example.

The symbol arrangement table specifies symbol position data (e.g., "0" to "19") indicating the position of each symbol in the rotation direction of each of the reels 3L, 3C, and 3R. Data for specifying the type of symbol (e.g., a symbol code) is also associated with each symbol position data. The symbol arrangement table also specifies that 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 "0". Note that the number of symbols in each row, the number of symbol types, the maximum number of sliding pieces, etc. can be changed and specified as appropriate.

[4-2. Design Combinations]
As described above, the slot machine 1 is designed so that the combination of the displayed symbols affects the game result. That is, the slot machine 1 can provide various benefits, move from the current state to a relatively advantageous state, or move from the current state to a relatively disadvantageous state, depending on the combination of the displayed symbols. Therefore, the main control circuit 100 must be configured to be able to grasp such combinations of symbols. For this reason, the main ROM 102 is provided with data for identifying such combinations of symbols. As long as such a purpose is achieved, various configurations can be adopted for the data configuration, and in this embodiment, the symbol combination table (see FIGS. 11 to 14) described below is used as an example.

The symbol combination table specifies data (e.g., "display role" or "win activation flag") indicating the type of combination of multiple predefined symbols among the symbol combinations that can be displayed on the winning line. The symbols that make up each symbol combination can be specified, for example, using the symbol code described above. Each symbol combination is also associated with data indicating the type of bonus (e.g., "payout, etc."). The symbol combination table basically has a data structure that corresponds to the winning flag storage area, the winning activation flag storage area, and the symbol code storage area (see FIG. 17), which will be described later. The number of types of symbol combinations, the contents of the bonus, etc., can be changed and specified as appropriate.

[4-3. Internal lottery]
As described above, the Pachislot machine 1 is designed so that which combination of symbols is permitted to be displayed (predetermined) affects the game result. That is, the Pachislot machine 1 is capable of determining the internal winning combination (i.e., the type of combination of symbols that can be displayed (or the type of benefit that can be awarded)) prior to (in advance of) the player's stop operation. Therefore, the main control circuit 100 must be configured to be able to grasp such an internal winning combination. For this reason, data for identifying such an internal winning combination is specified in the main ROM 102. Note that, as long as such a purpose is achieved, various configurations can be adopted for the data configuration, and in this embodiment, an internal lottery table (see FIG. 10) described later is used as an example.

The internal lottery table specifies data indicating the types of multiple predefined internal winning roles (for example, "No." or "winning number") and lottery values that determine each internal winning role in each game state. The lottery values may vary depending on the set value. Each internal winning role is also associated with a type of (corresponding) pattern combination that is permitted to be displayed. In addition, the pachislot machine 1 allows multiple pattern combinations to be associated with one internal winning role, and when such an internal winning role is determined, the pattern combination that is displayed is determined by the stop control.

Here, for example, in the internal lottery process of this embodiment described later (see FIG. 26; more specifically, the internal winning combination determination process of S64), first, a random number value extracted from a predetermined numerical range (e.g., 0 to 65535) by a random number circuit is sequentially added and updated with a lottery value specified corresponding to each internal winning combination. Next, a determination is made as to whether or not the lottery result (lottery value + random number value) exceeds 65535 (whether or not the lottery result has overflowed). Then, if the result of this determination exceeds 65535 for a given internal winning combination, the internal winning combination is made to win (the internal winning combination is determined). However, if none of the internal winning combinations exceeds 65535 even after this determination has been made for all internal winning combinations, the internal winning combination for this game will be a "lose". Note that this is merely one example of the internal lottery process, and various methods can be used for the lottery process as long as an appropriate lottery is performed according to the lottery value (winning probability). For example, the extracted random number value may be sequentially subtracted and updated by a lottery value specified for each internal winning combination, and then the internal winning combination may be determined by determining whether the subtraction result (lottery result) is below 0 (whether the lottery result has underflowed).

In this way, in the internal lottery table, the larger the lottery value specified for an internal winning role, the higher the probability of it being determined (winning probability). The winning probability of each internal winning role can be expressed as "lottery value specified for each winning number / number of all random number values that can be drawn (random number denominator: 65536)".

[4-4. Stop control]
As described above, the slot machine 1 is designed such that the game result is affected by which combination of symbols is finally displayed by the player's stop operation among the combinations of symbols permitted to be displayed by the determination of the internal winning role. That is, the slot machine 1 is capable of performing control (stop control) to vary (determine) the type of the combination of symbols finally displayed not only by the type of the determined internal winning role, but also by the timing of the player's stop operation and the order of pressing (also called "stop operation mode" or "stop operation procedure"). Therefore, the main control circuit 100 must be configured to be able to grasp in what mode the stop control is performed for each internal winning role according to the player's stop operation mode. For this reason, the main ROM 102 is provided with data for specifying such a mode of stop control. Note that, as long as such a purpose is achieved, various configurations can be adopted for the data configuration, and in this embodiment, a stop table and a pull-in priority table (not shown) are used as an example.

In the stop table, data indicating the amount of movement of the symbols (for example, the "number of sliding pieces") is specified for each symbol position data of the reels 3L, 3C, and 3R. For example, suppose that a specified stop table is selected in a game in which a specified internal winning combination is determined. Next, suppose that a stop operation is performed on the reel 3L during rotation. At this time, suppose that the stop start position (the symbol position data of the middle area of the reel 3L when the stop operation is performed) is "0". And suppose that the number of sliding pieces specified for the symbol position data "0" in the specified stop table is "4". Then, the main control circuit 100 performs control so that the reel 3L is stopped at a symbol position (the position of the symbol position data "4") that has moved by four symbols (the planned stop position becomes "4"). In this way, the stop table specifies data (the number of sliding pieces) that makes it possible to directly determine the stop position. Note that this data configuration is merely one example. Also, performing stop control using such a stop table is generally called "table control".

The attraction priority table specifies data (e.g., "attraction priority order") indicating which symbol combination is to be preferentially displayed (attracted) when there are multiple symbol combinations permitted to be displayed. For example, assume that a specified attraction priority order table is selected in a game in which a specified internal winning combination is determined. Here, the specified internal winning combination permits the display of symbol combination A and symbol combination B, and the specified attraction priority order table specifies attraction priorities such that symbol combination B is preferentially displayed over symbol combination A. Next, assume that a stop operation is performed on reel 3L while it is spinning. At this time, assume that the stop start position is "0".

Then, the main control circuit 100 searches for the presence of the symbols constituting the symbol combination A and the symbols constituting the symbol combination B for each symbol position within the range of the maximum number of sliding pieces (for example, "4") including the stop start position. If both symbols are not present, the position to stop is determined according to a predetermined rule (for example, to stop at a closer position, to stop at a farther position, etc.). If only the symbols constituting the symbol combination A are present, it is determined to stop at a position corresponding to the symbol. If only the symbols constituting the symbol combination B are present, it is determined to stop at a position corresponding to the symbol. If both symbols are present, it is determined to stop at a position corresponding to the symbol constituting the symbol combination B, since the symbol combination B is displayed preferentially over the symbol combination A. Note that the pull-in priority order may be stored for all symbol positions during the rotation of the target reel according to the selected pull-in priority order table, or may be stored for each symbol position within the range of the maximum number of sliding pieces including the stop start position when a stop operation is performed on the target reel. Also, such a data configuration is merely one example. In addition, using such a pull-in priority table to perform stop control is generally referred to as "control control."

In this embodiment, the stop control can be configured to be executed by performing only "table control" or by performing only "control control". Alternatively, the stop control can be configured to first tentatively determine the stopping position by performing "table control", then search for a more appropriate stopping position by performing "control control", and then change the stopping position depending on the search results.

In this way, in the pachislot machine 1, the combination of symbols that will ultimately be displayed on the pay line is determined based on, for example, the following three factors:

The first element is the determined internal winning role (lottery result of the internal lottery process). For example, if the result of the internal lottery process is a "miss," then none of the combinations of symbols related to any replay role, combinations of symbols related to minor roles, or combinations of symbols related to bonus roles will ultimately be displayed on the winning line. Note that a "miss" can be considered to be one of the internal winning roles, or it can be considered to be a lottery result in which no internal winning role has been determined.

The second element is the timing of the player's stop operation (the position of the symbols (pressed position) when the player operates one of the stop buttons). For example, in this embodiment, the maximum number of sliding pieces is set to four symbols, so even if one of the internal winning roles is won as a result of the internal lottery process, if the symbols that make up a combination of symbols that are allowed to be displayed are positioned on an active line (or each active line if there are multiple), the combination of symbols may not be displayed depending on the timing of the player's stop operation. This is known as a "miss."

The third element is the player's push order (the order in which the player operates the stop button). For example, in this embodiment, an internal winning role associated with a combination of multiple symbols may be determined, and in this case, the combination of symbols that is ultimately displayed on the winning line may vary depending on the player's push order. Such an internal winning role is called a "push order role", and if it is a replay role, it may be called a "push order replay", and if it is a minor role, it may be called a "push order minor role".

[4-5. Game Status]
In the pachislot machine 1, in order to vary the degree of advantage of the player or to provide a desired gaming experience, it is possible to provide various gaming states as a state in which the game is played. An example of the gaming state will be described below.

[4-5-1. Bonus state]
In the pachislot machine 1, when a bonus role is won and a symbol combination related to the bonus role is displayed on an active line, it is possible to transition to a bonus state (activate the bonus state). It is also possible to configure the machine not to provide such a bonus state. It is also possible to configure the machine to provide multiple bonus states by providing multiple types of bonus roles. When a bonus role is won, a state (carry-over state) occurs in which the bonus role is carried over as an internal winning role over multiple games until the symbol combination related to the bonus role is displayed on an active line. Such a bonus role is sometimes called a "carry-over role". Also, such a carry-over state is sometimes called a "(bonus) flag interval" or "(bonus) internally in progress", etc.

The bonus state is a state in which it is possible to vary the lottery mode of the minor role (including the probability of winning and its contents, or the mode of stop control, etc.; the same applies below) compared to a state in which the bonus state is not activated (non-bonus state) (since it is also a state in which it is possible to vary the lottery mode of the replay role, the bonus state can also be considered as one mode of the RT state described below). Therefore, if such a lottery mode is a lottery mode that is relatively advantageous to the player, the bonus state is a more advantageous gaming state 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 is a less advantageous gaming state than the non-bonus state.

Examples of bonus roles include a first type special role (RB), a role continuous operation device (BB) related to a first type special role, a second type special role (CB) (but not a carryover role), a role continuous operation device (MB) related to a second type special role, and a normal role (SB) (but not a carryover role). For example, the bonus states corresponding to each bonus role are configured as follows. The RB state is configured as a game state that ends when a predetermined arbitrary number of winnings (e.g., the upper limit is 8 times) or a predetermined arbitrary number of games (e.g., the upper limit is 12 times) have been played. The BB state is configured as a game state that ends when a predetermined arbitrary number of payouts (e.g., the upper limit is 285 coins) has been paid out.

The CB state is configured as a game state that ends when one game has been played. The MB state is configured as a game state that ends when more than a predetermined number of medals have been paid out (for example, the upper limit is 153 medals) or when RB or SB is won during the MB state. The SB state is configured as a game state that ends when one game has been played.

The condition for the bonus state to be activated is not limited to the display of a combination of symbols related to the bonus role on the pay line. For example, during the operation of the consecutive activation device (BB) related to the first type special role, the first type special role (RB) can be automatically activated when the consecutive activation device (BB) related to the first type special role starts to operate, when the game starts when the first type special role is not in operation, or when the operation of the first type special role ends. In other words, it is possible to control the RB to always be in operation during the operation of the BB without specifying the combination of symbols related to the RB. Here, the RB during the operation of the BB is sometimes called "JAC" and the like, and the specification in which the RB automatically operates during the operation of the BB is sometimes called "auto JAC". Also, during the operation of the BB, it is possible to control the RB to be in operation when the combination of symbols related to the specified RB is displayed on the pay line. The specification in which the RB operates based on the display of the corresponding combination of symbols in this way is sometimes called "manual JAC". The same applies to the relationship between the special feature continuous operation device (MB) for the second type special feature and the second type special feature (CB). In other words, it is possible to control the CB to be in operation at all times while the MB is in operation without specifying the combination of symbols related to the CB, and it is also possible to control the CB to be in operation when the specified combination of symbols related to the CB is displayed on the winning line while the MB is in operation.

[4-5-2. RT state]
In the pachislot machine 1, when a predetermined transition condition is established, it is possible to transition to the RT state (activate the RT state). It is also possible to configure the machine so that such an RT state is not provided. It is also possible to configure the machine so that multiple RT states are provided. The RT state is a state in which the lottery mode of the replay role can be changed with respect to a state in which 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 game state that is more advantageous than the non-RT state. On the other hand, when such a lottery mode is a lottery mode that is relatively disadvantageous to the player, the RT state becomes a game state that is less advantageous than the non-RT state. In addition, when multiple RT states are provided, the same applies to between the multiple RT states. In this case, an RT state in which the lottery pattern for the replay role (particularly, the probability of winning) is relatively favorable to the player may be referred to as a "high RT state" or a "high probability re-play state", and an RT state in which the lottery pattern for the replay role (particularly, the probability of winning) is relatively unfavorable to the player may be referred to as a "low RT state" or a "low probability re-play state".

The RT state can be transitioned, for example, when any of the following transition conditions are satisfied. In addition, when multiple RT states are provided, the same applies to transitions between the multiple 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) When a specific combination of symbols is displayed when RB, BB or MB has not been won (not carried over) and the player is not in the RB state, BB state or MB state; (5) When a predetermined number of plays have been played after the transition condition of (3) or (4) is met.

[4-5-3. AT state]
In the pachislot machine 1, when a predetermined transition condition is met, it is possible to transition to the AT state (activate the AT state). It is also possible to configure the machine so that such an AT state is not provided. It is also possible to configure the machine so that multiple AT states are provided. The AT state is a game state that is configured as a more advantageous state than a state in which the AT state is not activated (non-AT state), for example, by notifying the player of information on a stop operation that is advantageous to the player when the above-mentioned push order role is won.

When multiple AT states are provided, the degree of advantage to the player can be varied by making the play period for each AT state (including the ease of extension if the period can be extended (or "topped up"; the same applies below)), the type of role for which information on a stop operation is notified, or the occurrence probability of notification of information on a stop operation different from each other. In addition, the transition conditions and end conditions for the AT state can be set appropriately according to the gameplay (excluding end due to execution of the limit process described below). In addition, the AT state may be treated as if it were the bonus state described above, in which case it may be called a "pseudo bonus state", etc.

In addition, the play period of the AT state may be managed by the number of games (play count) as long as the period is appropriately managed (game count management), or may be managed by the number of sets with a predetermined number of games as one set (set count management). It may also be managed by the number of payouts or net increase (difference in number of coins) during the AT state (payout number management, difference in number of coins management). It may also be managed by the number of notifications (number of navigations) that affect the payout of medals in the AT state (for example, push order navigation when a push order minor role is won) (navigation count management). The same applies when the AT state is extended. The play period granted when transitioning to the AT state and the play period granted when the AT state is extended may be managed by different management methods. In addition, when multiple AT states are provided, they may be managed by the same management method or different management methods.

[4-5-4. ART state]
In the pachislot machine 1, when a predetermined transition condition is satisfied, it is possible to transition to an ART state that combines the above-mentioned high RT state and AT state (activate the ART state). That is, since the ART state means an AT state that is performed in a high RT state, the ART state differs from the AT state in that at least a low RT state and a high RT state are provided as RT states, and control is performed to transition to the high RT state (or transition to the low RT state is avoided), but the basic control is the same as the AT state (if the transition to the high RT state (or transition to the low RT state is avoided) is the result of information on a stop operation that is advantageous to the player being notified, it can be said to be synonymous with the AT state). In addition, when the transition condition of the ART state is satisfied, it may be a state that first transitions to the AT state and then transitions to the high RT state to transition to the ART state, or a state that transitions to the high RT state and the AT state simultaneously (or approximately simultaneously) to transition to the ART state.

[4-5-5. Other game states]
In addition, the pachislot machine 1 can also provide game states other than the various game states described above. For example, each mode in the advantageous zone (see FIG. 5 and FIG. 6) described later is a state in which the player plays a game, and can change the degree of advantage of whether or not to transition to the AT state as a pseudo bonus state, so these can be considered as game states. From a similar perspective, for example, a game state can be provided that can change the degree of advantage of whether or not to transition to a bonus state. For example, when a bonus role is won (carried over), a game state in which a combination of symbols related to the bonus role is more likely to be displayed by stop control and a game state in which the combination of symbols related to the bonus role is less likely to be displayed relatively than this can be provided so that the degree of advantage of the player can be changed. In addition, for example, it is possible to configure the game so that the degree of advantage of the player can be varied by providing a game state in which a bonus role is won with a predetermined probability (easy to win) and a game state in which the bonus role is won with a probability lower than the predetermined probability (relatively difficult to win).

In addition, the following methods can be adopted as a method for varying the degree of advantage of whether or not to transition to an AT state (which may also include whether or not to extend the play period of the AT state while in the AT state; the same applies below). For example, a "special role" can be determined as an internal winning role. The number of medals awarded for the special role varies depending on the player's stop operation mode (which may be the timing of the stop operation, the order in which the buttons are pressed, or a combination of these) (for example, if the stop operation mode is appropriate (correct), eight medals are paid out, and if the stop operation mode is inappropriate (incorrect), one medal or none is paid out).

If the specific combination is won in a specific game state, and eight coins are paid out, then no decision is made as to whether or not to change the degree of advantage of transitioning to an AT state in the current game to a more advantageous one (this may include a decision as to whether or not to transition directly to the AT state, or whether or not to directly extend the game period of the AT state; hereafter referred to as "advantage decision"). On the other hand, if eight coins are not paid out, then that advantage decision is made in the current game. Alternatively, if the specific combination is won in the above-mentioned specific game state, and eight coins are paid out, then that advantage decision is made in the current game. On the other hand, if eight coins are not paid out, then that advantage decision is not made in the current game.

In this way, when a player plays using a specific game method, it is possible to configure the system so that, as a result of the game, an advantageous decision is made in the current game, or the advantageous decision is not made (the advantageous decision is restricted). Note that the player may change between the current game and the next game, and if such restrictions continue into the next game and beyond, there is a risk that the (next) player may suffer a significant disadvantage. Therefore, it is desirable that such restrictions only apply to the current game and not continue into the next game and beyond. Such restrictions are also sometimes referred to as "penalties."

[4-6. Playing area]
In the pachislot machine 1, in order to prevent excessive gambling, it is possible to provide various game zones as game states with concepts different from the above-mentioned game states. An example of such a game zone will be described below. The game zone is roughly divided into a non-advantageous zone and an advantageous zone.

(Non-advantageous section)
The non-advantageous section is configured as a game period during which it is not possible to notify the player of an advantageous stop operation mode, and has the following requirements. Note that the following requirements are merely examples, and if at least one of the requirements is relaxed or tightened, the requirements can be appropriately changed accordingly.

(1) It is not possible to inform the player of advantageous stop operation modes (for example, push order navigation, etc.). Therefore, it is not possible to control to the above-mentioned AT state or ART state.
(2) When the setting value is changed (settings are changed), or when an initialization condition such as a "RAM abnormality" described below is met, a non-advantageous zone is set as the initial state.
(3) When the limit process described below is executed in the favorable zone (i.e., when a predetermined value (e.g., the value of the favorable zone game number counter or favorable zone payout counter described below) that is updated as play progresses during the favorable zone becomes a specified value (e.g., 1,500 games or 2,400 coins)), a non-favorable zone is set as the initial state. Note that the predetermined value may be referenced, and if the predetermined value becomes a specific updated value even before it becomes a specified value, a non-favorable zone may be set using that as a condition. Also, when a predetermined termination condition is met during the favorable zone and the zone is determined to end (e.g., when a lottery for the end of the favorable zone is held and the lottery is won), a non-favorable zone may be set using that as a condition.
(4) In a non-advantageous zone, processing related to the advantageous zone (for example, processing to determine whether or not to transition to an advantageous zone) can only be performed by referring to the determined internal winning role, and processing cannot be performed by referring to various parameters other than the internal winning role, such as the derived result display (combination of symbols) and the number of games in the non-advantageous zone (or the advantageous zone before transition). Note that which internal winning role has been determined can be determined by referring to data that directly indicates the internal winning role, such as a winning number, or by referring to data that indirectly indicates the internal winning role, such as a sub-flag (where multiple roles are treated as one determination target data) generated or converted from the data of the internal winning role.
(5) The non-advantageous zone is basically in state 1, and multiple states cannot be set within the non-advantageous zone. For example, it is not possible to set different states, such as the non-advantageous zone after the end of the advantageous zone being non-advantageous zone A, and the non-advantageous zone after the setting change being non-advantageous zone B.

(Advantageous area)
The advantageous section is configured as a game period during which the player can be notified of advantageous stop operation modes, and has the following requirements. Note that the following requirements are merely examples, and if at least one of the requirements is relaxed or tightened, the requirements can be appropriately changed accordingly.

(1) It is possible to notify the player of advantageous stop operation modes (for example, push order navigation, etc.). Therefore, it is possible to control to the above-mentioned AT state or ART state.
(2) If the setting value is changed (settings are changed), or if an initialization condition such as a "RAM abnormality" described below is met, it is not possible to set the advantageous zone as the initial state.
(3) If the limit processing described below is executed in a favorable zone, the favorable zone must be terminated.
(4) In the advantageous zone, processing related to the advantageous zone (for example, processing to determine whether or not to shift the game state (mode) during the advantageous zone, or whether or not to extend a specific game state (mode)) can be performed not only by referring to the determined internal winning combination, but also by referring to various parameters other than the internal winning combination, such as the derived result display (combination of symbols) and the number of games played during the advantageous zone. Other examples of the various parameters that can be referred to include, for example, bonus information such as points that can be awarded according to the various parameters described above, the type of bonus state, the type of RT state, the timing of the stop operation of any of the reels, or the push order.
(5) A plurality of states can be set within the advantageous zone. For example, a normal state that is disadvantageous to the player, a CZ state that is easy to transition to an AT state, or an AT state in which the expected value of medal increase is positive when a stop operation is performed according to the notification can be set. In addition, for example, a CZ premonition state that is set as a standby state until the actual transition to the CZ state in response to a decision to transition to the CZ state in the normal state, and a premonition performance that suggests the transition to the CZ state can be performed, or an AT premonition state that is set as a standby state until the actual transition to the AT state in response to a decision to transition to the AT state in the normal state or the CZ state, and a premonition performance that suggests the transition to the AT state can be performed, can also be set according to the gameplay.
(6) The fact that the vehicle is in a favorable zone can be notified by lighting up the zone lamp (status display unit) that can notify whether the zone is a non-favorable zone or a favorable zone (if the zone lamp is off, it can notify that the vehicle is in a non-favorable zone). As described above, the timing at which the zone lamp starts to light can be set to any timing. Basically, the zone lamp may start to light up when the vehicle moves from a non-favorable zone to a favorable zone and continue to light up until the vehicle moves to the non-favorable zone, or the zone lamp may not start to light up when the vehicle moves from a non-favorable zone to a favorable zone (the favorable zone has started) and the favorable zone to which the vehicle has moved is in a normal state, and may start to light up when the vehicle first enters the AT state. If the favorable zone to which the vehicle has moved is in the AT state, the light may start to light up from that point on.

[4-7. Limiter]
In the pachislot machine 1, in order to prevent the advantageous zone from continuing too long and becoming excessively gambling-oriented, it is possible to set an upper limit (restriction) on the period during which the advantageous zone continues. Such an upper limit is called a "limiter." In this embodiment, the end of the advantageous zone by such a limiter is described as the execution of a limit process or the activation of a limiter. An example of the limiter will be described below.

(Game number limiter)
The game number limiter is configured as a limiter that executes a limit process when the number of games (number of plays) in the advantageous zone reaches "1500". For example, the advantageous zone game number counter described later starts counting when the advantageous zone starts, and increments the count by one each time one play is played. Then, based on the value of the advantageous zone game number counter reaching a specified value (for example, "1500" or more), the advantageous zone is forcibly ended (for example, even if the play period of the AT state remains) and a transition is made to a non-advantageous zone. Note that the number of games that activates the game number limiter can be set to any number of games as long as it is equal to or less than the upper limit of "1500". In addition, when the requirements of such a game number limiter are relaxed or tightened, it can be appropriately changed accordingly. In addition, it may be a type that gradually suppresses gambling according to the number of games in the advantageous zone.

(Payout limiter)
The payout number limiter is configured as a limiter that executes a limit process when the number of medals paid out during the favorable zone reaches "2400". For example, the favorable zone payout number counter described later starts counting when the favorable zone starts, and adds the corresponding number of medals each time a medal is paid out (more specifically, the net increase obtained by subtracting the number of bets from the number of payouts). Then, based on the value of the favorable zone payout number counter reaching a specified value (e.g., "2400" or more), the favorable zone is forcibly ended (e.g., even if the game period in the AT state remains), and the zone is shifted to a non-favorable zone. Note that the payout number at which the payout number limiter operates can be set to any payout number as long as it is equal to or less than the upper limit of "2400". In addition, when the requirements for such a payout number limiter are relaxed or tightened, it can be appropriately changed accordingly. In addition, it may be a type that gradually suppresses gambling according to the number of medals paid out during the favorable zone.

Also, for example, the advantageous zone payout number counter described below may be configured to count the positive amount from the most recent lowest point, with the point where the absolute value of the number of medals has decreased the most since the start of the advantageous zone as the lowest point (starting point) (i.e., the count is subtracted if there is no payout). In other words, the payout number limiter may be configured as a limiter that executes limit processing when a maximum of "2400" medals have been paid out since the medals increase during the advantageous zone (for example, when the AT state begins). Also, for example, the advantageous zone payout number counter described below may simply count the actual payout number (i.e., the number of medals paid out without subtracting the number of bets from the number of medals), rather than the net increase mentioned above.

The pachislot machine 1 may execute the limit processing of the advantageous zone using only the game count limiter, may execute the limit processing of the advantageous zone using only the payout number limiter, or may execute the limit processing of the advantageous zone using both the game count limiter and the payout number limiter. Note that when both limiters are used, it is desirable to end the advantageous zone when the activation condition of either one of the limiters is satisfied after the advantageous zone has started.

The types of limiters are not limited to the game number limiter and payout number limiter described above. For example, a navigation count limiter may be provided that executes limit processing when the number of times push order minor roles are navigated during the AT state (i.e., the number of times information on stop operations advantageous to the player is notified for roles related to the payout of medals) reaches a predetermined number (e.g., "400" times). In other words, as long as gambling can be appropriately suppressed, it is possible to execute limit processing using various conditions related to the game.

[4-8. External Signals]
As described above, the pachislot machine 1 is designed to be capable of outputting a plurality of types of external signals to the outside. For example, if the 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 can also perform the bonus state performance linked thereto. Also, for example, if the external signal 1 is turned on based on the start of the BB state, turned off based on the end of the BB state, turned on based on the start of the MB state, and turned off based on the end of the MB state, the external data display device can not only perform the above-mentioned bonus state performance, but also count the number of bonuses by type.

Furthermore, for example, if external signal 1 is turned on when an AT state is started, and turned off when the AT state is ended, then an AT state performance linked to this can be performed on the external data display.Furthermore, for example, if external signal 1 is turned on when a specific AT state is started, and turned off when the specific AT state is ended, and external signal 2 is turned on when a specific AT state is started, and turned off when the specific AT state is ended, then not only can the external data display perform the above-mentioned AT state performance, but the number of ATs can be counted by type.

For example, if the AT state is configured as an AT state managed by the number of sets, and external signal 1 is turned on when the first set of the AT state starts, and external signal 2 is turned on each time the second set and subsequent sets start, the number of first hits in the AT state and the number of times the AT state is extended can be counted on the external data display. The timing for turning on and off each external signal can be set as appropriate. In other words, as long as the situation is properly recognized by the external data display or hall computer, 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 until it turns off again, such as a predetermined time, during one game, or until the state changes.

[4-9. Commands]
As described above, the slot machine 1 is designed to be capable of transmitting multiple types of commands from the main control circuit 100 to the sub-control circuit 200. Note that the slot machine 1 does not allow the main control circuit 100 and the sub-control circuit 200 to communicate with each other, and is required to communicate only in one direction from the main control circuit 100 to the sub-control circuit 200. Therefore, the main control circuit 100 needs to transmit information (commands) to the sub-control circuit 200 at appropriate times to notify the sub-control circuit 200 of changes in the state of the slot machine 1. An example of such a command will be described 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 the setting value, game status, etc. Also, for example, when a bet operation is performed, a medal insertion command is transmitted. The medal insertion command includes parameters for specifying the number of bets, etc. Also, for example, when a start operation is performed, a start command is transmitted. The start command includes parameters that specify the internal winning role, game status, etc. Also, for example, when a lock effect is performed, a lock command is transmitted. The lock command includes parameters that specify the content of the lock effect, etc. Also, for example, when the rotation of each reel 3L, 3C, 3R starts, a reel rotation start command is transmitted. The reel rotation start command includes parameters that specify that the rotation of the reels has started, etc.

Also, for example, when a stop operation is performed, a reel stop command is sent. The reel stop command is configured to include parameters that specify the reel to be stopped and the position where the reel is stopped. Also, for example, when all reels are stopped and the displayed role (winning activation flag) is confirmed, a winning activation command is sent. The winning activation command is configured to include parameters that specify the type of displayed role and the content of the bonus to be granted. Also, for example, when a favorable zone is started, a favorable zone start command is sent. The favorable zone start command is configured to include parameters that specify the start of the favorable zone and the mode (game state), etc. Also, for example, when a favorable zone is ended, a favorable zone end command is sent. The favorable zone end command is configured to include parameters that specify the end of the favorable zone and the cause of the end. Also, for example, when a settlement operation is performed, a settlement command is sent. The settlement command is configured to include parameters for specifying the number of returns, etc. Note that these are merely examples, and commands other than these can be sent as necessary, and unnecessary commands among these can be not sent.

[4-10. Direction］
As described above, in the pachislot machine 1, in order to increase the interest of the game, to inform the player of useful information, or to realize the intended gameplay, various effects are executed using various effect devices. An example of such a presentation will now be described.

[4-10-1. Main side production]
In the slot machine 1, the main control circuit 100 (main side) can control the following effects, for example. As described above, the slot machine 1 can notify the user of information on the stop operation by the instruction monitor, and this is also included in the effects in a broad sense.

(Rock performance)
In the pachislot machine 1, when a predetermined execution condition is met, an effect may be performed in which the progress of the game is stopped for a predetermined period of time (the game operation of the player is disabled for a predetermined period of time). Such an effect is called a "lock effect (or simply "lock")" or a "freeze effect (or simply "freeze")". It is possible to configure the machine so that such a lock effect is not performed, or to configure the machine so that multiple types of lock effects are performed.

The gaming operation to be invalidated may be, for example, a start operation, a stop operation, or another operation. For example, if a start operation is invalidated for a specified period of time, the progress of the game is stopped for a specified period of time after all stop operations have been performed. For example, if a stop operation is invalidated for a specified period of time, the progress of the game is stopped for a specified period of time after a start operation has been performed. If multiple types of lock effects are provided, the period during which the game progress is stopped (the period during which the player's gaming operation is invalidated) and the type of gaming operation to be invalidated may be set for each lock effect.

(Reel production)
In the pachislot machine 1, when a predetermined execution condition is met, an effect can be performed by the effect display mode of each reel 3L, 3C, 3R (including not only the variable display mode but also a combination with the stopped display mode) during the execution of the above-mentioned lock effect. Such effects are called "reel effects" as well as "symbol effects", etc. Note that it is possible to configure the machine so that such reel effects are not performed, or to configure the machine so that multiple types of reel effects can be performed. In addition, when it is said that "a lock effect is performed (executed)", this also includes both cases where a reel effect is performed and cases where it is not performed.

In short, the reel effects are produced by spinning or stopping (temporarily stopping) each of the reels 3L, 3C, and 3R without the player's input during a period in which the player's input is disabled. Therefore, it is possible to set an operation pattern that performs such an output operation without considering the rotation speed or the maximum number of sliding pieces. Furthermore, by setting multiple operation patterns, multiple types of reel effects can be provided. Furthermore, by combining multiple types of reel effects with multiple types of lock effects, an even wider variety of output patterns can be set. Note that only one, any two, or all three of the reels 3L, 3C, and 3R may be used for the reel effects.

(Pseudo-game)
In the pachislot machine 1, when a predetermined execution condition is met, a performance in which a pseudo game is performed during the execution of the above-mentioned lock performance can be performed. Such a performance is called a "pseudo game." It is possible to configure the machine so that such a pseudo game is not performed, or to configure the machine so that multiple types of pseudo games can be performed. In addition, when "a lock performance is performed (executed)," it also includes both cases where a pseudo game is performed and cases where it is not performed.

In short, pseudo-games accept the player's game operations in a pseudo manner during a period in which the player's game operations are invalid, and perform effects by spinning or stopping (temporarily stopping) each of the reels 3L, 3C, and 3R. In other words, the above-mentioned reel effects are further performed by intervening the player's game operations. Note that, for example, the MAX BET button 6a, 1 BET button 6b, start lever 7, each of the stop buttons 8L, 8C, and 8R, and the settlement button 9, etc. are basically provided for the purpose of being used for game operations, and therefore it is not desirable to use them for any other purpose. However, pseudo-games allow these operations to be accepted, on the premise that measures are taken to prevent the player from mistaking that they are playing an actual game.

Here, the flow of the pseudo game will be described with an example. The pseudo game is carried out, for example, in the following manner.
(1) The player's actual start operation (when the execution conditions are met, the pseudo game begins)
(2) Each reel rotates in a simulated manner (during simulated play)
(3) Accepts a pseudo-stop operation, which temporarily stops each reel (during pseudo play)
(4) After a random delay process, the reels actually start spinning (the simulated game ends and the actual game begins).

The random delay process is a process that randomly generates a delay period for each reel before starting its rotation (such a delay period is also called a "rearrangement period") to correct the situation where, for example, if certain symbols are displayed in a line in the above situation (3) and the reels start to rotate normally in the above situation (4), the player may be more likely to use the certain symbols as a landmark to stop the reels (this may aid in the so-called "eye-pressing" technique). In addition, when the reels are temporarily stopped in the above situations (3) and (4), it is desirable to ensure that the phase signal in the excitation control of each stepping motor is always less than a certain time (e.g., 500 ms) so that the reels are alternately changed between forward and reverse directions, so that they are not mistaken for being completely stopped.

One of the above-mentioned measures, for example, is to slightly vibrate (swing) each reel up and down when any combination of symbols is temporarily stopped in the above-mentioned situation (3) (when the third reel is temporarily stopped and then all reels are temporarily stopped) until the random delay process is started in the above-mentioned situation (4). Note that, as long as the phase signal changes within the above-mentioned predetermined time, such swinging may not be performed when the first reel is temporarily stopped and when the second reel is temporarily stopped.

As one of the above-mentioned measures, for example, a pseudo game lamp is provided to notify the player that a pseudo game is being played, and the pseudo game lamp is turned on from when the pseudo game starts in the above-mentioned (1) situation until the random delay process starts in the above-mentioned (4) situation. The pseudo game lamp is preferably installed above the operation unit that accepts the player's game operation and in a position that is visible during the game. The pseudo game lamp is preferably an independent lamp that is not used for other purposes, and the entire display unit of the pseudo game lamp is preferably covered with a monochromatic border. The pseudo game lamp is preferably such that the display range, including the explanatory portion of the pseudo game lamp, has a certain surface area (for example, one side is more than 10 mm and the surface area is more than 642 square mm, etc.). In addition, it is preferable that the description of the pseudo game lamp is written so that it can be recognized that the pseudo game lamp is a lamp to notify that a pseudo game is in progress (for example, "FREE PLAY", "pseudo game performance in progress", or "automatic reel performance in progress"), and it is preferable that such description occupies at least 1/3 of the surface area. Note that the pseudo game lamp may be controlled by the main control circuit 100 or the sub-control circuit 200.

As one of the above-mentioned measures, for example, a pseudo-game display to inform the player that a pseudo-game is being played may be displayed on the main display device 210 or the sub display device 220 (or both) from the start of the pseudo-game in the above-mentioned (1) situation until the start of the random delay process in the above-mentioned (4) situation. The pseudo-game display is preferably displayed above the operation unit that accepts the player's game operation and at a position that is visible during the game (in this embodiment, since both the main display device 210 and the sub display device 220 are above the operation unit, either one may be used). In addition, it is preferable that the display range of the pseudo-game display, including its explanatory portion, has a certain surface area (for example, one side exceeds 10 mm, the surface area exceeds 642 square mm when the display screen is less than 7 inches, and the surface area is 8.2% or more of the entire screen when the display screen is 7 inches or more). Additionally, it is desirable for the explanatory portion of the pseudo-play display to be written in a way that makes it clear that the pseudo-play display is intended to inform the player that a pseudo-play is in progress (for example, "FREE PLAY," "pseudo-play performance in progress," or "automatic reel performance in progress"), and it is desirable for the explanatory portion to be large enough for the player to read without being obscured or otherwise hidden.

Also, for example, during the pseudo game (for example, from the start of the pseudo game in the above-mentioned situation (1) to the start of the random delay processing in the above-mentioned situation (4)), it is desirable to configure so that information on the stop operation is not notified on the instruction monitor (if it is necessary to display information on the stop operation on the instruction monitor in the game, the display is started at the timing when the random delay processing is started). In this way, it is possible to further prevent the player from misunderstanding that an actual game is being played during the pseudo game. Note that, if any of the above measures are taken, during the pseudo game, information on the stop operation may be notified on the sub-side presentation device (for example, the main display device 210 or the sub-display device 220). Similarly, during the pseudo game, the sub-side presentation device may perform a presentation according to the game result of the pseudo game (linked to the pseudo game operation).

In addition, in an actual game, a test signal corresponding to the player's game operation or the state in which the game operation is possible is output through the first interface board 301 for the test machine, but during a pseudo game, a 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 a pseudo game, a test signal (pseudo game signal) may be output to enable the test machine to recognize that a pseudo game is being played. In addition, when the first interface board 301 for the test machine receives a pseudo game signal from the main control board 71, the first interface board 301 may output a signal for controlling the pseudo game progress to the main control board 71 so that the pseudo game progresses on the main control board 71 side (i.e., the first interface board 301 for the test machine may be provided with a pseudo game progress function). In addition, when the first interface board 301 for the test machine is provided with such a pseudo game progress function, a switch capable of switching the function on and off may be provided. This makes it possible to arbitrarily set whether or not to check the content of the simulated game during the certification test (test firing test) of the pachislot machine 1.

[4-10-2. Sub-side production]
In the slot machine 1, the sub-control circuit 200 (sub-side) can control the following effects, for example. As described above, the slot machine 1 can notify the player of information on the stop operation by the main display device 210, etc., and this is also included in the effects in a broad sense.

(Normal performance)
In the pachislot machine 1, when a predetermined execution condition is met, a performance that is completed in the current game (i.e., ends in one game) can be performed. This type of performance is called a "normal performance" or a "single-shot performance". It is possible to configure the machine so that such a normal performance is not performed, or to configure the machine so that multiple types of normal performances can be performed.

(Continuous performance)
In the pachislot machine 1, when a predetermined execution condition is satisfied, a performance that continues over a number of games (i.e., continues for a number of games) can be performed. Such a performance is called a "continuous performance" or a "continuous performance". It is possible to configure the machine so that such a continuous performance is not performed, or to configure the machine so that a number of types of continuous performance can be performed.

(Operation-linked effects)
In the pachislot machine 1, when a predetermined execution condition is established, an effect can be performed in which the effect content can be changed according to the effect operation of the player. Such an effect is called an "operation-linked effect" or a "button effect" or the like. Note that it is possible to configure the device so that such an operation-linked effect is not performed, or to configure the device so that multiple types of operation-linked effects can be performed. In addition, the operation-linked effect can be configured as a normal effect, or as a continuous effect. In addition, the effect operation can include not only an operation on the effect button group, but also various game operations.

The various effects described above can be used for various purposes. For example, they can be used to suggest or notify the set value, internal lottery role, game status, game section, bonus content, and the period until the bonus is granted. They can also be used to suggest or notify the degree of advantage of these. These uses are merely examples.

(Other performances)
In the pachislot machine 1, it is also possible to perform effects other than the various effects described above. For example, various notifications (e.g., addiction prevention notification, loss prevention notification, error state notification, demo state notification, etc.) to players or gaming establishments that are used for purposes other than those described above are also included in the effects in a broad sense. The addiction prevention notification can be, for example, a warning or the like that is issued when the advantageous zone ends. The loss prevention notification can be, for example, a warning or the like that is issued when the advantageous zone ends or when a settlement operation is performed. The error state notification can be, for example, a warning or the like that is issued from the time an error occurs until it is resolved. The demo state notification can be, for example, a notification that the machine is vacant when a period of no play reaches a predetermined period or when a settlement operation is performed.

[5. First gaming machine]
Next, referring to Figures 5 to 22, a specific example of the specifications related to the playability of the pachislot machine 1 will be described as a "first gaming machine". Note that, with respect to the various specifications and functions described as the first gaming machine in this embodiment, a part or all of them can be applied to those described as other gaming machines in this embodiment, and, further, with respect to the various specifications and functions described as other gaming machines in this embodiment, a part or all of them can be applied to those described as the first gaming machine in this embodiment. In other words, an appropriate combination of these can be the invention according to this embodiment.

First, in the first gaming machine, the active line is defined as only one line, the "center line" mentioned above. In addition, in the first gaming machine, a non-bonus state and a bonus state are provided as gaming states. In addition, the non-bonus state includes a 2BB flag interval in which "F_2BB" (a bonus role that can only be won in a two-coin bet state; hereinafter, it may be simply referred to as "2BB") is carried over, a 3BB flag interval in which "F_3BB" (a bonus role that can only be won in a three-coin bet state; hereinafter, it may be simply referred to as "3BB") is carried over, and a non-flag interval in which no bonus role has been won (not carried over). In addition, the bonus state includes a 2BB state to which a transition occurs in response to the display of a combination of symbols related to 2BB, and a 3BB state to which a transition occurs in response to the display of a combination of symbols related to 3BB.

The first gaming machine allows players to play with two medals bet (two-bet state) and three medals bet (three-bet state). Note that "betting" includes the player inserting two or three medals into the medal insertion slot 5 for play, the player operating the MAX BET button 6a or 1 BET button 6b to bet two or three medals from credits, and the player automatically betting two or three medals when a replay role is won.

[5-1. Gaming Characteristics of the First Gaming Machine]
Next, the flow of the game in the first gaming machine will be described with reference to Figures 5 to 8. Note that Figure 5 is a diagram showing an example of a transition flow of the game state in the non-advantageous zone and the advantageous zone in the first gaming machine, Figure 6 is a diagram for explaining an example of each mode in the first gaming machine, and Figures 7 and 8 are diagrams showing an example of various tables in the first gaming machine.

As shown in FIG. 5, in the first gaming machine, the states in which the player plays are broadly divided into non-advantageous zones and advantageous zones, and the advantageous zones are further divided into presentation zones (advantageous zones, normal play) and increase zones (advantageous zones, pseudo bonus). The non-advantageous zones are game states (non-AT states) in which information on stop operations that are advantageous to the player is not notified, and are game states that are disadvantageous to the player. The presentation zones are game states (non-AT states) in which information on stop operations that are advantageous to the player is not notified, and are game states that are disadvantageous to the player, similar to the non-advantageous zones, but differ from the non-advantageous zones in that mode transitions are performed, as described below.

In other words, the non-advantageous zone is the control state in the initial state that is controlled when play in the advantageous zone ends, when a setting change operation is performed, when other initialization conditions are met, or when the machine is shipped from the factory, etc., and the performance zone is the control state in the normal state in which the player plays normally, making it possible to vary the expectation of transitioning to the increased zone (awarding) by mode transitions, etc.

On the other hand, the increase section is a game state (AT state) in which information about a stop operation that is advantageous to the player is notified, and is an advantageous game state for the player. In other words, the increase section is a control state that is an advantageous state in which the player can increase the number of medals. Note that both the performance section and the increase section are advantageous sections, and by transitioning between these sections, a series of advantageous sections are formed.

In the first gaming machine, as shown in FIG. 7(a), in the non-advantageous zone, a non-advantageous zone sub-flag is determined as secondary information (sub-flag) corresponding to the internal winning role (see FIG. 10 described later). The sub-flag is information for grouping internal winning roles that play similar roles (whether or not they are lottery-eligible roles and their winning probability, etc.) in various lotteries related to playability by the main control circuit 100 (various processes related to the advantageous zone) and assigning the same information to the group, making it possible to identify the group. This eliminates the need to provide various data tables for each internal winning role, making it possible to compress the amount of data and avoid straining the capacity of the main ROM 102. In the non-advantageous zone, a lottery is held using this non-advantageous zone sub-flag.

The non-advantageous zone sub-flag "Rip Bell" is determined when the internal winning role is any of "F_Replay A" (No. "3"), "F_Replay B" (No. "4"), and "F_Bell 123A1" to "F_Bell 321B2" (No. "10" to "33"). The non-advantageous zone sub-flag "Weak Cherry" is determined when the internal winning role is "F_Cherry" (No. "5"). The non-advantageous zone sub-flag "Watermelon" is determined when the internal winning role is "F_Watermelon" (No. "9"). The non-advantageous zone sub-flag "Determined Role" is determined when the internal winning role is any of "F_Determined Cherry" (No. "6") and "F_Reach Eye" (No. "8"). The non-advantageous zone sub-flag "middle cherry" is determined when the internal winning role is "F_middle Cherry" (No. "7"). Note that the non-advantageous zone can also be configured so that the winning sub-flag and the winning sub-flag can be determined, just like the advantageous zone. Furthermore, the correspondence between these is not limited to the above.

In addition, in the first gaming machine, as shown in FIG. 7(a), in the advantageous zone, a sub-flag at the time of winning the advantageous zone is determined as secondary information (sub-flag) corresponding to the internal winning role (see FIG. 10 described below). Furthermore, in the advantageous zone, a sub-flag at the time of winning the advantageous zone is determined as secondary information (sub-flag) corresponding to the combination of the displayed symbols. In the advantageous zone, a lottery is held using these sub-flags at the time of winning the advantageous zone and the sub-flag at the time of winning the advantageous zone.

The sub-flag "Bell" when the advantageous zone is won is determined when the internal winning role is any of "F_Bell 123A1" to "F_Bell 321B2" (No. "10" to No. "33"). The sub-flag "Weak Cherry" when the advantageous zone is won is determined when the internal winning role is "F_Cherry" (No. "5"). The sub-flag "Watermelon" when the advantageous zone is won is determined when the internal winning role is "F_Watermelon" (No. "9"). The sub-flag "Definite Role" when the advantageous zone is won is determined when the internal winning role is either "F_Definite Cherry" (No. "6") or "F_Reach Eye" (No. "8"). The sub-flag "Middle Cherry" when the advantageous zone is won is determined when the internal winning role is "F_Middle Cherry" (No. "7").

The sub-flag "Tsu-Rip 1" when entering the favorable zone is determined when the internal winning role is either "F_Replay A" (No. "3") or "F_Replay B" (No. "4") and the symbol combination "Right Up Rip" is displayed (i.e., the winning role is "Right Up Rip"). The sub-flag "Tsu-Rip 2" when entering the favorable zone is determined when the internal winning role is either "F_Replay A" (No. "3") or "F_Replay B" (No. "4") and the symbol combination "Parallel Rip" is displayed (i.e., the winning role is "Parallel Rip").

Here, in the first gaming machine, as described below, when the internal winning combination is "F_Replay A" (No. "3"), a "Right-Rising Replay" symbol combination is displayed between 3BB flags, and a "Parallel Replay" symbol combination is displayed between 2BB flags and non-flags.

In other words, when the internal winning combination is "F_Replay A" (No. "3"), "Tsu Replay 1" is determined as the sub-flag when the player enters the advantageous zone between 3BB flags, and "Tsu Replay 2" is determined as the sub-flag when the player enters the advantageous zone between 2BB flags and non-flags. In the first gaming machine, when the sub-flag when the player enters the advantageous zone differs in this way, the degree of advantage in the various lotteries described below (for example, the pseudo bonus transition lottery using the pseudo bonus transition lottery table shown in FIG. 7(c) and the mode transition lottery using the mode transition lottery table shown in FIG. 8(f)) is changed.

In the first gaming machine, for example, "F_Replay A" (No. "3") is used as an example of a role in which the sub-flag changes when the player enters a favorable zone depending on whether the player is between 3BB flags or 2BB flags, but the manner in which the sub-flag changes when the player enters a favorable zone is not limited to this. For example, as described below, when the internal winning role is "F_Bell 123B1" (No. "12"), the stop control is different between the 3BB flag and the 2BB flag. Therefore, when such a role is won, the number of medals paid out may not change (or may change), but the combination of the displayed symbols may be different, and a different sub-flag may be determined when the player enters a favorable zone. Then, the degree of advantage in the various lotteries described below may be changed depending on the difference in the sub-flag when the player enters a favorable zone.

Also, for example, as described below, when the internal winning role is "F_watermelon" (No. "9"), regardless of which flag interval (non-flag interval) it is, if the pressing position (stop operation timing) is appropriate, the "watermelon" symbol combination is displayed, and if the pressing position is not appropriate, a miss occurs and the "watermelon spill" symbol combination is displayed. Therefore, when such a role is won, different sub-flags for winning the advantageous zone may be determined depending on whether a win is achieved without a miss or whether a miss occurs. Then, the degree of advantage in the various lotteries described below may be changed depending on whether the sub-flag for winning the advantageous zone is different.

Also, for example, when the internal winning role is "F_Replay A" (No. "3"), if the stopping operation is performed in a specific manner (this specific manner may be, for example, a manner in which the stopping operation is performed in a predefined hitting order (correct pressing order), a manner in which the pressing position (timing of the stopping operation) is appropriate, or a manner in which a combination of these is performed) between the 3BB flags, a combination of symbols of "parallel replay" is displayed, and if the stopping operation is not performed in the specific manner, a combination of symbols of "right-up replay" is displayed, and different sub-flags for when the player enters the advantageous zone may be determined based on this. Then, the degree of advantage in the various lotteries described below may be varied depending on the different sub-flags for when the player enters the advantageous zone.

In other words, the first gaming machine allows the final stop display mode for a specific combination to differ depending on the number of bets, the game state, the mode of the stop operation, or any combination of these, and allows different secondary information to be determined according to different stop display modes, thereby applying all the modes that allow the degree of advantage to be changed.

Returning to the description of the playability of the first gaming machine, in the non-advantageous zone, a lottery for transition to the advantageous zone is held for each game. Specifically, the advantageous zone transition lottery table shown in FIG. 7(b) is referenced, an internal winning combination is determined, and at a predetermined timing during the game after the non-advantageous zone sub-flag is determined according to the internal winning combination, the transition mode, etc. is determined according to the non-play zone sub-flag. Note that, when making this determination, there are cases where only the type of mode when transitioning to the advantageous zone is determined (in FIG. 5, "Advantageous Zone Start"), and cases where not only the type of mode but also a transition to a pseudo bonus is determined (in FIG. 5, "Advantageous Zone Start + Pseudo Bonus Start"). However, it is also possible to configure the specification so that a transition to a pseudo bonus is not determined in the non-advantageous zone.

Now, referring to FIG. 6, the various modes in the first gaming machine will be described. In the first gaming machine, the mode is control information (which may also be referred to as the game state or control state) for varying the expectation of a transition (award) to an increase zone (pseudo bonus) in the presentation zone (normal play), and in the presentation zone (normal play), it is according to this mode that a decision is made as to whether or not a pseudo bonus transition will occur, whether an advantageous zone will be maintained, or whether the advantageous zone will end and a transition will be made to a non-advantageous zone.

The start mode is a relatively disadvantageous mode in which a player is likely to stay when transitioning from a non-advantageous zone to an advantageous zone (performance zone), and the expectation of transitioning to a pseudo bonus is relatively low (see FIG. 7(c) described below), and the expectation of transitioning to a more advantageous mode is also relatively low (see FIG. 8(f) described below). Although not shown in the figure, in the start mode, the ceiling game number is set to "965 games." The ceiling game number is used to forcibly transition to a pseudo bonus when a certain period of time has elapsed without transitioning to a pseudo bonus. Therefore, the smaller the ceiling game number, the more advantageous it is for the player, and the higher the ceiling game number, the more disadvantageous it is for the player.

The normal A mode is the mode in which players are most likely to stay when playing, and is a relatively disadvantageous mode, so the expectation of transitioning to a pseudo bonus is relatively low (see FIG. 7 (c) described below), and the expectation of transitioning to a more advantageous mode is also relatively low (see FIG. 8 (f) described below). In the normal A mode, the ceiling game number is set to "965 games". In addition, in FIG. 6, "approximately 999G after pseudo bonus" means that after the pseudo bonus ends, the game transitions to the end A mode or end B mode described below, and 32 games are played in that mode without transitioning to a pseudo bonus, and after transitioning to a non-advantageous zone once, if the normal A mode is selected when transitioning from the non-advantageous zone to the advantageous zone, the apparent ceiling game number is "965 games" + the play period "32 games" in the end A mode or end B mode + the number of games required to transition from the non-advantageous zone to the advantageous zone, so this is expressed. The same applies to the normal B mode, the heaven preparation mode, and the chance mode.

Normal B mode is a mode in which players tend to stay relatively easily while playing, and although it is a relatively disadvantageous mode, it is more advantageous than normal A mode, and the expectation of transitioning to a pseudo bonus is relatively low (see FIG. 7(c) below), and the expectation of transitioning to a more advantageous mode is also relatively low (see FIG. 8(f) below). In normal B mode, the ceiling number of games is set to "965 games."

In the Heaven Preparation Mode, the likelihood of transitioning to a pseudo bonus is relatively low (see Figure 7 (c) below), but the ceiling number of games is set at 466 games, and if a transition is made to a pseudo bonus, it is guaranteed that the mode will transition to Heaven Mode after the end of the pseudo bonus (see Figure 8 (f) below), making it a relatively advantageous mode in that sense.

In Chance mode, the expectation of moving to the pseudo bonus is relatively high (see Figure 7 (c) below), and the ceiling number of games is set to "222 games," so in that sense it is a relatively advantageous mode. However, the expectation of moving to Heaven mode is not high (see Figure 8 (f) below).

End A mode is a relatively unfavorable mode in which players are likely to remain if they transition to a pseudo bonus and do not transition to heaven mode (including heaven preparation mode) after the pseudo bonus ends, and the expected probability of transitioning to a pseudo bonus is the lowest (see FIG. 7(c) below), and the expected probability of transitioning to a more favorable mode is also relatively low (see FIG. 8(f) below). In End A mode, if 32 games are played after the pseudo bonus ends without transitioning to a pseudo bonus, the favorable zone itself ends and a transition occurs to a non-favorable zone.

End B mode is a relatively unfavorable mode in which players are likely to stay if they transition to a pseudo bonus and do not transition to heaven mode (including heaven preparation mode) after the pseudo bonus ends, but it is more favorable than end A mode, and the expectation of transitioning to a pseudo bonus is relatively low (see FIG. 7(c) below), and the expectation of transitioning to a more favorable mode is also relatively low (see FIG. 8(f) below). In end B mode, like end A mode, if 32 games are played after the pseudo bonus ends without transitioning to a pseudo bonus, the favorable zone itself ends and the player transitions to a non-favorable zone. End A mode and end B mode can also be collectively referred to as "end modes".

The guaranteed mode is the mode in which you stay when Heaven C mode ends, and since the expectation of moving to a pseudo bonus is relatively high (see FIG. 7(c) below), and the ceiling number of games is set to "32 games," in that sense it is a relatively advantageous mode. However, the expectation of moving to Heaven mode is not high (see FIG. 8(f) below). In other words, in order to prevent a drop in interest when Heaven C mode ends, the guaranteed mode is positioned as one that aims to maintain (guarantee) a relatively advantageous state for a certain period of time.

Heaven A mode is a mode where you can expect a series of pseudo bonuses (if the AT state is continued by a decision to extend (add) during the AT state, this may also include the extension (addition). The same applies below), and the expectation of transitioning to a pseudo bonus is relatively high (see (c) in FIG. 7 described later), the ceiling number of games is set to "32 games", and the probability of maintaining the ceiling mode (heaven mode loop rate) is set to a medium level, making it a relatively advantageous mode. Although not shown in FIG. 6, for example, a setting difference can be set for this ceiling mode loop rate. For example, when the setting value is an odd number (1, 3, 5), the ceiling mode loop rate is about 75%, and when the setting value is an even number (2, 4, 6), the lottery value can be set so that the ceiling mode loop rate is about 67%, or the lottery value can be set so that the higher the setting value, the higher the ceiling mode loop rate. The same applies to the heaven B mode and heaven C mode described later, and a setting difference can be set for the ceiling mode loop rate.

Heaven B mode is a mode in which pseudo bonuses can be expected to appear consecutively, the expectation of transitioning to a pseudo bonus is relatively high (see FIG. 7(c) below), the ceiling number of games is set to "32 games", and the probability of maintaining the ceiling mode (heaven mode loop rate) is set high, making it a relatively advantageous mode. In other words, in terms of the ceiling mode loop rate, it is an even more advantageous mode than Heaven A mode.

Heaven C mode is a mode in which pseudo bonuses can be expected to appear consecutively, the expectation of transitioning to a pseudo bonus is relatively high (see FIG. 7(c) below), the ceiling number of games is set to "32 games", and the probability of maintaining the ceiling mode (heaven mode loop rate) is set quite high, making it a relatively advantageous mode. In other words, in terms of the ceiling mode loop rate, it is a more advantageous mode than Heaven A mode and Heaven B mode. Heaven A mode, Heaven B mode, and Heaven C mode can be collectively referred to as "heaven mode".

Note that the above modes are merely examples, and the mode configuration is not limited to these. Modes other than the above modes can be set, and some of the above modes can be chosen not to be set.

Up to this point, the non-advantageous zone has been described as being in a state where the degree of advantage is relatively low compared to the advantageous zone, but the relationship between the non-advantageous zone and the advantageous zone is not limited to this. For example, the non-advantageous zone may have a higher transition rate to the increasing zone than the advantageous zone when at least one mode is set, or the average number of games required to transition to the increasing zone may be shorter, or the non-advantageous zone may be the zone that is most likely to become the increasing zone. By doing this, an incentive to play is created even in a state where it is confirmed that the zone is a non-advantageous zone after a setting change, etc., so that it is a motivation to start playing even from the time the store opens. Even if the zone lamp stops lighting when 32 games have passed after the pseudo bonus ends, it is not confirmed that the zone is in the most disadvantageous state, so that it is a motivation to continue playing even in such a case. Up to this point, the performance zone has been described as a game state in which information on a stop operation that is advantageous to the player is not notified, but if it is in a state that is disadvantageous compared to the increasing zone (for example, by lowering the frequency of notification or changing the role that is the subject of notification), it can also be a game state in which information on a stop operation is notified.

Returning to the description of the playability of the first gaming machine, in the performance section (normal play), first, for each play, a pseudo bonus transition lottery (at the time of winning) is performed by referring to the sub-flag at the time of winning the advantageous section. Specifically, the pseudo bonus transition lottery table shown in FIG. 7(c) is referred to, an internal winning role is determined, and at a predetermined timing during the play after the sub-flag at the time of winning the advantageous section is determined according to the internal winning role, it is determined whether or not to transition to a pseudo bonus according to the sub-flag at the time of winning the advantageous section. In FIG. 7(c), "non-winning" means that there is no transition to a pseudo bonus, "winning (current play)" means that there is a transition to a pseudo bonus from the current play, and "winning (next play)" means that there is a transition to a pseudo bonus from the next play.

In the first gaming machine, if a "winning lottery (current game)" is determined, game operations (stop operations) are invalidated for a certain period of time at the start of the current game, and if a "winning lottery (next game)" is determined, at the start of the next game. During this invalid period, a reel effect in which "red 7" symbols are displayed in the main display window 4 (a "red 7s aligned" effect) is performed, and then a pseudo bonus is started. In a game in which a "red 7s aligned" effect is performed, if it is necessary to notify information about the stop operation, the information about the stop operation is notified at least when the invalid period ends and game operations (stop operations) become valid (it may be before that, but not before the timing when the random delay process described above is started).

If the pseudo bonus transition lottery (when drawn) in the performance section (normal play) determines that a transition to a pseudo bonus will occur, a mode transition lottery (when drawn) is held. Specifically, the mode transition lottery table shown in FIG. 8(f) is referenced, and the transition mode is determined according to the current mode and the sub-flag when the advantageous section is drawn. Note that this transition mode may be a mode including the pseudo bonus, or may be a mode after the pseudo bonus ends. Also, if the pseudo bonus transition lottery (when drawn) determines that a transition to a pseudo bonus will occur and a mode transition lottery (when drawn) is held, the pseudo bonus transition lottery (when winning), mode transition lottery (when winning), and mode transition lottery (when reaching the ceiling) described below are not held.

If the pseudo bonus transition lottery (when drawn) does not determine a transition to a pseudo bonus in the presentation section (normal play), then for each play (more specifically, in a play in which "F_Replay A" or "F_Replay B" is drawn), a pseudo bonus transition lottery (when a win occurs) is held by referring to the sub-flag when entering the favorable zone. Specifically, the pseudo bonus transition lottery table shown in FIG. 7(c) is referenced to determine the winning combination, and at a predetermined timing during the play (before the start of the next play) after the sub-flag when entering the favorable zone is determined according to the winning combination, it is determined whether or not to transition to a pseudo bonus according to the sub-flag when entering the favorable zone.

In the pseudo bonus transition lottery table shown in FIG. 7(c), the probability of deciding to transition to a pseudo bonus is higher when "Tsū Rip 2" is determined as the sub-flag when entering an advantageous zone than when "Tsū Rip 1" is determined as the sub-flag when entering an advantageous zone. However, the manner in which "Tsū Rip 2" is given preferential treatment over "Tsū Rip 1" is not limited to this. For example, when "Tsū Rip 2" is determined as the sub-flag when entering an advantageous zone, it may be determined to transition to a pseudo bonus with a predetermined probability, but when "Tsū Rip 1" is determined as the sub-flag when entering an advantageous zone, it may be possible to prevent the decision to transition to a pseudo bonus.

If the pseudo bonus transition lottery (when winning) in the performance section (normal play) determines that a transition to a pseudo bonus will occur, a mode transition lottery (when winning) is held. Specifically, the mode transition lottery table shown in FIG. 8(f) is referenced, and the transition mode is determined according to the current mode and the sub-flag when winning the advantageous section. Note that this transition mode may be a mode including the mode during the pseudo bonus, or may be a mode after the pseudo bonus ends. Also, if the pseudo bonus transition lottery (when winning) determines that a transition to a pseudo bonus will occur and a mode transition lottery (when winning) is held, the mode transition lottery (when ceiling) described below is not held.

In the mode transition lottery table shown in FIG. 8(f), the probability of deciding to transition to a mode that is relatively advantageous to the player is higher when "Tsū-Rip 2" is determined as the sub-flag when entering an advantageous zone than when "Tsū-Rip 1" is determined as the sub-flag when entering an advantageous zone. However, the manner in which "Tsū-Rip 2" is given preferential treatment over "Tsū-Rip 1" is not limited to this. For example, when "Tsū-Rip 2" is determined as the sub-flag when entering an advantageous zone, it may be determined with a predetermined probability that the player will be transitioned to a mode that is relatively advantageous to the player, but when "Tsū-Rip 1" is determined as the sub-flag when entering an advantageous zone, it may be possible to prevent the player from deciding to transition to a mode that is relatively advantageous to the player.

If the pseudo bonus transition lottery (when a prize is won) does not determine a transition to a pseudo bonus in the presentation section (normal play), the ceiling game number is updated (this can be by addition or subtraction), and if the ceiling game number reaches the ceiling game number associated with the current mode (or determined in advance when transitioning to a favorable section, etc.), a transition to a pseudo bonus is determined. In this case, it is possible to always determine a "winning lottery (current play)," or it is also possible to always determine a "winning lottery (next play)." It is also possible to have either of these be determined by lottery.

When the ceiling number of games is reached during the presentation section (normal play) and it is decided to transition to a pseudo bonus, a mode transition lottery (at the ceiling) is held. Specifically, the mode transition lottery table shown in FIG. 8 (f) is referenced, and the mode to transition to is determined according to the current mode. This mode to transition to may be a mode including the mode during the pseudo bonus, or may be a mode after the pseudo bonus ends.

The processing related to the pseudo bonus transition lottery (when a prize is won) and the pseudo bonus transition lottery (when a prize is won) differs only in the type of sub-flag, and the rest of the processing is the same, so they can be controlled using the same lottery table and control flow.The processing related to the mode transition lottery (when a prize is won) and the mode transition lottery (when a prize is won) differs only in the type of sub-flag, and the rest of the processing is the same, so they can be controlled using the same lottery table and control flow.

Also, if "Winning lottery (played this time)" is not set as a type of pseudo bonus winning lottery, then at the time the sub-flag for winning the advantageous zone is determined, the sub-flag for winning the advantageous zone has already been determined, and the ceiling game number can also be updated, so the pseudo bonus transition lottery (when winning), the pseudo bonus transition lottery (when winning), and the pseudo bonus transition processing when the ceiling is reached can be performed together in a single process. Similarly, the mode transition lottery (when winning), the mode transition lottery (when winning), and the mode transition lottery (when the ceiling is reached) can also be performed together in a single process.

Returning to the explanation of the playability of the first gaming machine, as described above, when a decision is made to transition to a pseudo bonus in the presentation section (normal play) and the pseudo bonus starts ("pseudo bonus start" in FIG. 5), the game transitions to the increase section (pseudo bonus). Also, as described above, when the presentation section (normal play) is controlled to end A mode or end B mode and 32 games are played without transitioning to a pseudo bonus ("end of favorable section (via ends A and B)" in FIG. 5), the game transitions to a non-favorable section. Also, when the conditions for the limit processing shown in FIG. 16 described below are met, the favorable section is forcibly ended ("end of favorable section (limit processing)" in FIG. 5), and as a result, the game transitions to a non-favorable section.

In the increase section (pseudo bonus), a ceiling shortening lottery is held when the pseudo bonus starts. Specifically, the ceiling shortening lottery table shown in FIG. 8(e) is referenced, and it is determined whether or not to shorten the ceiling number of games after the pseudo bonus ends depending on the current mode. In FIG. 8(e), "non-winning" means that the ceiling number of games will not be shortened, and "winning (updated ceiling number of games = 0)" means that the ceiling number of games set will be set to "0" (shortened) after the pseudo bonus ends, regardless of the mode. The ceiling shortening lottery can be held not only when the pseudo bonus starts, but also every time the pseudo bonus is played.

If the result of the ceiling shortening lottery is that the ceiling game number will not be shortened, and if the player does not have a 1G consecutive stock (described below) when the pseudo bonus ends, the ceiling game number will be set according to the current mode (in the end mode, the advantageous zone ends after 32 games (and is cleared accordingly), so the ceiling game number is not set, but the ceiling game number may be provisionally set here), the pseudo bonus ends (in FIG. 5, "pseudo bonus end"), and the performance zone (normal play) begins. On the other hand, if the result of the ceiling shortening lottery is that the ceiling game number will be shortened, the ceiling game number will be set to "0 games" when the pseudo bonus ends. This means that the pseudo bonus will start again from the next play after the pseudo bonus ends. In this case, the pseudo bonus will start when the ceiling game number is reached, so the mode transition lottery (at ceiling) described above will be performed.

In the increase section (pseudo bonus), a mode transition lottery (when drawn) is held for each game (more specifically, in a game in which the sub-flag when the advantageous section is drawn is determined to be "guaranteed role" or "medium chain"). Specifically, the mode transition lottery table shown in FIG. 8(f) is referenced, and the transition mode is determined according to the current mode and the sub-flag when the advantageous section is drawn. Note that the transition mode may also be determined when a sub-flag when the advantageous section is drawn other than the above. In this case, in principle, in order to prevent a mode that is relatively less favorable than the current mode from being determined as the transition mode, a different mode transition lottery table with a different lottery value from the mode transition lottery table shown in FIG. 8(f) may be referenced.

In the increase zone (pseudo bonus), a mode transition lottery (when winning) is held for each game (more specifically, in a game in which "F_Replay A" or "F_Replay B" is won). Specifically, the mode transition lottery table shown in FIG. 8(f) is referenced, and the mode to transition to is determined according to the current mode and the sub-flag when the advantageous zone is won. In this case, as with the above, in order to prevent a mode that is relatively less favorable than the current mode from being determined as the mode to transition to, a different mode transition lottery table with a different lottery value from the mode transition lottery table shown in FIG. 8(f) may be referenced.

In the increase section (pseudo bonus), a 1G consecutive draw is performed for each game. Specifically, the 1G consecutive draw table shown in FIG. 7(d) is referenced, and whether or not a 1G consecutive draw will occur is determined according to the current mode and the sub-flag when the advantageous section is drawn or the sub-flag when the advantageous section is won. In FIG. 7(d), "non-win" means that a 1G consecutive draw will not occur, and "win (1G consecutive + 1)" means that one right to generate a 1G consecutive draw (1G consecutive stock) is granted (the 1G consecutive stock counter is incremented by 1). Note that multiple 1G consecutive stocks (up to 255) can be stocked (accumulated) by the 1G consecutive stock counter. Therefore, multiple 1G consecutive stocks may be granted during one pseudo bonus. The 1G consecutive draw table can also be configured so that multiple 1G consecutive stocks can be granted in one 1G consecutive draw.

When the pseudo bonus ends, if the value of the 1G consecutive stock counter is 1 or more (i.e., if you have 1G consecutive stock), one 1G consecutive stock is consumed (the 1G consecutive stock counter is decremented by 1), and the pseudo bonus will start again from the next game after the pseudo bonus ends. In this case, since the pseudo bonus starts according to the right of 1G consecutive stock, the above-mentioned mode transition lottery is not held. On the other hand, when the pseudo bonus ends, if the value of the 1G consecutive stock counter is not 1 or more (i.e., if you do not have 1G consecutive stock), and if you have not won the above-mentioned ceiling shortening lottery, the ceiling game number is set according to the current mode (in the end mode, the advantageous period ends after 32 games (and is cleared accordingly), so it is not set, but the ceiling game number may be provisionally set here), the pseudo bonus ends (in FIG. 5, "pseudo bonus end"), and the game moves to the performance period (normal game).

In addition, if a player wins the ceiling shortening lottery and also has 1G consecutive stocks, the result of the ceiling shortening lottery may be prioritized and a pseudo bonus corresponding to the ceiling shortening may be executed after the pseudo bonus corresponding to the 1G consecutive stocks, or the 1G consecutive stocks may be prioritized and a pseudo bonus corresponding to the 1G consecutive stocks may be executed after the pseudo bonus corresponding to the ceiling shortening. In the latter case, information that allows the existence of a ceiling shortening to be carried over may be stored separately.

In the first gaming machine, the configuration of the increase section (pseudo bonus) is given as an example in which it continues for "55 games" and a maximum of 275 coins can be obtained, but the configuration of the pseudo bonus is not limited to this. For example, the pseudo bonus may be configured as a "pseudo BB (big bonus)" and a "pseudo RB (regular bonus)" that continues for "22 games" and allows a maximum of 110 coins to be obtained may be installed. In this case, when it is decided to transition to a pseudo bonus (to grant the right) in the pseudo bonus transition lottery, when the ceiling is reached, and in the 1G consecutive lottery, the type (e.g., whether to select "pseudo BB" or "pseudo RB") may be determined with a predetermined probability (e.g., 50% each). In addition, the "pseudo RB" may have a different value from the "pseudo BB" (more specifically, a lower value than the "pseudo BB"). For example, the number of continuing games may be the same as the "pseudo BB", but the maximum number of coins that can be won may be different by lowering the Bernavi rate (probability of announcing information on a stop operation). When the "pseudo RB" is started, a reel effect may be performed in which the "BAR" symbols are aligned in the main display window 4, or a reel effect may be performed in which "red 7-red 7-BAR" is displayed. Furthermore, the increase section is not limited to being configured as a pseudo bonus. For example, it may be configured as an AT state or an ART state in which the number of continuing games (play period) can be changed.

In addition, if the conditions for executing the limit processing shown in FIG. 16 described below are met during the pseudo bonus, the advantageous zone will be forcibly ended ("End of advantageous zone due to limit processing" in FIG. 5), resulting in a transition to a non-advantageous zone.

In the first gaming machine, the above-mentioned game flow is based on the premise that the game is basically played with three coins bet. Therefore, when playing with two coins bet, for example, various lotteries using (a)-(d) in FIG. 7 and (e) and (f) in FIG. 8 are not conducted, and the ceiling number of games is not updated. In addition, when playing with two coins bet during a pseudo bonus, the pseudo bonus is not an increase period because the machine is configured so that medals do not increase when two coins are bet. In other words, the first gaming machine is basically configured so that the player is at a disadvantage when playing with two coins bet.

Here, when playing in the two-coin bet state, no lottery (e.g., various lotteries using (a)-(d) of FIG. 7, (e) and (f) of FIG. 8, etc.) or processing (e.g., updating of the ceiling game number, etc.) is performed for the advantageous zone (AT), but it is desirable to update the advantageous zone game number counter for the game number limiter described above and the advantageous zone payout number counter for the payout number limiter described above. These limiters have the function of appropriately suppressing gambling by restricting the number of games stayed in the advantageous zone and the upper limit of the number of coins won. If these counters were not updated in the two-coin bet state, there would be cases where the upper limit of the number of games stayed in the advantageous zone or the number of coins won set would be exceeded due to play in the two-coin bet state, and as a result, gambling would not be appropriately suppressed.
Therefore, it is desirable that the limiter counter be configured so that it can be updated every game regardless of the number of bets.

In addition, in the first gaming machine, the above-mentioned game flow is basically premised on the premise that the game is played in a non-bonus state. Therefore, when the game is played in a bonus state (2BB state and 3BB state), for example, various lotteries using (a) to (d) in FIG. 7, (e) and (f) in FIG. 8, etc. are not conducted, and the ceiling number of games is not updated. In addition, when the bonus state is entered during a pseudo bonus, the bonus state is configured as a state in which the expected increase in medals is lower than in a non-bonus state (more specifically, a non-bonus state with 3 medals bet), so the pseudo bonus may not be an increase period. In other words, the first gaming machine is configured so that playing in a bonus state may put the player at a disadvantage.

Therefore, the first gaming machine is configured to recommend playing in the 3-coin bet state between 2BB flags (in this embodiment, the 3-coin bet state between 2BB flags may be described as the "recommended gaming state", and other states may be described as the "non-recommended gaming state"). That is, in the first gaming machine, 2BB is a bonus role that can only be won in the 2-coin bet state, and the combination of symbols related to 2BB between 2BB flags only wins in the 2-coin bet state, and does not win in the 3-coin bet state. Also, 3BB is a bonus role that can only be won in the 3-coin bet state, and the combination of symbols related to 3BB between 3BB flags only wins in the 3-coin bet state, and does not win in the 2-coin bet state. Also, 3BB does not win between 2BB flags, and 2BB does not win between 3BB flags.

The first gaming machine uses these configurations to, for example, win 2BB (without winning 2BB) in a 2-coin bet state with no flags, resulting in a 2BB flag, and then play in a 3-coin bet state, making it possible to play in the recommended game state described above without worrying about winning a bonus role.

As described above, in the first gaming machine, a ceiling shortening lottery is held during the pseudo bonus. Looking at the ceiling shortening lottery table shown in FIG. 8(e), when the current mode is either the guaranteed mode, the heaven A mode, the heaven B mode, or the heaven C mode, there is a probability of 1/8 (32/256) of winning the ceiling shortening lottery, whereas in other modes, there is no winning the ceiling shortening lottery. In other words, in a mode where the ceiling game count is "32 games," the "32 games" may be shortened to "0 games," and in a mode where the ceiling game count is greater than that, the ceiling game count is never shortened.

Even in the case of a mode in which the ceiling number of games is greater than "32 games," it may be determined that the ceiling number of games will be shortened with a lower probability (e.g., 1/64) than in the case of a mode in which the ceiling number of games is "32 games."

The manner in which the ceiling number of games is shortened is not limited to the above. For example, the same effect can be achieved by shortening "32 games" to a fewer number of games (0-31 games). Therefore, the number of games to be shortened when the ceiling shortening lottery is won may be determined, or the number of games to be shortened in the ceiling shortening lottery may be determined in advance.

The trigger for the ceiling shortening lottery is not limited to the above. For example, during a pseudo bonus, the ceiling shortening lottery may be performed for each game. Also, in the advantageous zone (normal play), when the current mode is any of the guaranteed mode, heaven A mode, heaven B mode, and heaven C mode, the ceiling shortening lottery may be performed for each game. In these cases, the sub-flag when the advantageous zone is won or the sub-flag when the advantageous zone is entered may be referenced to determine whether or not to win the ceiling shortening lottery.

As mentioned above, in the first gaming machine, a 1G consecutive lottery is held during the pseudo bonus. Looking at the 1G consecutive lottery table shown in FIG. 7(d), it can be seen that a 1G consecutive stock may be awarded regardless of the current mode. In other words, the right to continue the pseudo bonus can be awarded regardless of whether the mode has a ceiling game count of "32 games" or not.

The manner in which the right is granted is not limited to the above. For example, in a mode in which the ceiling game number is "32 games," a 1G consecutive lottery may not be conducted in consideration of the fact that a ceiling shortening lottery will be conducted, and in a mode in which the ceiling game number is greater than "32 games," a 1G consecutive lottery may be conducted, thereby preventing the game from becoming excessively gambling-oriented.

The trigger for the 1G consecutive lottery is not limited to the above. For example, the 1G consecutive lottery may be performed in advantageous zones (performance zones) other than the pseudo bonus, and the 1G consecutive stocks accumulated as a result may be consumed in the next pseudo bonus.

Although not shown in Figures 5 to 8, in the first gaming machine, when the pseudo bonus starts or during the pseudo bonus, a special bonus performance is executed with a predetermined probability to suggest that the current mode is the heaven mode and that the player is in an advantageous state. Therefore, when the special bonus performance is executed, the player can expect that the ceiling shortening lottery will be executed. This special bonus performance may be executed with a 100% probability when the ceiling shortening lottery is won. In this way, for example, when the special bonus performance is executed at the start of the pseudo bonus, it is suggested that the player is at least in the heaven mode, and the player can be made to have a sense of expectation that the ceiling shortening lottery may also be won. This special bonus performance may also be executed with a predetermined probability or 100% probability when the 1G consecutive lottery is won during the pseudo bonus. In this way, various possibilities can be suggested, such as (1) Heaven mode only, (2) Heaven mode + ceiling shortening lottery, (3) Heaven mode + 1G consecutive lottery, (4) Heaven mode + ceiling shortening lottery + 1G consecutive lottery, (5) 1G consecutive lottery only, etc., which can increase the interest of the game.

In this way, in the first gaming machine, if it is determined that the advantageous state (e.g., pseudo bonus) will be controlled again within a predetermined period (e.g., 32 games) after the end of the advantageous state, this period may be further shortened (e.g., in the case of heaven mode), so that even if the playing period of a series of advantageous zones is limited (e.g., when limit processing is executed), it is possible to prevent a decline in the interest of the game by allowing the player to play in as advantageous a state as possible.

In addition, in the first gaming machine, even if it is not certain that the advantageous state will be restored within a predetermined period of time after the advantageous state ends (for example, in the case of end mode), the advantageous state may be restored by granting a right (for example, 1G consecutive stock), which can heighten the player's expectations and increase the enjoyment of the game.

Although not shown in Figures 5 to 8, in the first gaming machine, when the sub-flag "Determined Role" is determined as the sub-flag when the advantageous zone is won (i.e., when "F_Determined Cherry" or "F_Reach Eye" is determined as the internal winning role), and when the result of the mode transition lottery described above is that the mode transition to Heaven C mode is decided, a special lock effect can be executed with a probability of 1/2 (this probability is arbitrary). Note that, even when the sub-flag "Middle Cherry" is determined as the sub-flag when the advantageous zone is won (i.e., when "F_Middle Cherry" is determined as the internal winning role), the player can receive the same benefit as when the sub-flag "Determined Role" is determined as the sub-flag when the advantageous zone is won, so when the sub-flag "Middle Cherry" is determined as the sub-flag when the advantageous zone is won, the special lock effect can be executed in the same way as when the sub-flag "Determined Role" is determined as the sub-flag when the advantageous zone is won.

Here, since the "fixed combination" is a combination that also determines the transition to the pseudo bonus (see FIG. 7(c)), when the special lock effect is executed, the player can recognize that the transition to the pseudo bonus and the transition to the Heaven C mode have occurred, which is very interesting for the player. The special lock effect is configured as an effect in which the game operation (stop operation) is invalid for about 20 seconds at the start of the game, for example. During this time, a special reel effect may be performed in which each reel vibrates or rotates in reverse, or a special video that is not normally displayed may be displayed on the main effect display unit 21. Also, a special song that is not normally output may be output. Of course, the effects may be performed by a combination of these. Also, although the game operation is not invalidated, these effects may be performed until the player performs the next game operation (i.e., the player may decide whether to execute the effect to the end or to cancel it midway and continue the game).

However, in the first gaming machine, as shown in FIG. 16 described below, even if the player is in Heaven C mode, the advantageous zone may be forcibly terminated by the execution of the limit process, so it may not be desirable to execute the above-mentioned special lock effect multiple times.

Therefore, in the first gaming machine, the special lock effect is executed only once within the same series of advantageous zones. Specifically, when it is decided to execute the special lock effect for the first time within a series of advantageous zones, the special lock effect is executed, but thereafter, even if the same conditions are met within the same series of advantageous zones, the special lock effect is controlled not to be executed. As a method, when the special lock effect is executed once, information indicating that is stored, and when the information is stored within the same series of advantageous zones thereafter, the decision on whether or not to execute the special lock effect may not be made in the first place, or the decision may be made, but when the information is stored, even if the decision result indicates execution, it may be rewritten to indicate no execution. Then, the stored information may be cleared when the advantageous zone ends.

The manner in which the execution of the special lock effect is restricted is not limited to the above. For example, the upper limit on the number of times the special lock effect can be executed may be set to "two times" or "three times" rather than "one time." In other words, the execution of the special lock effect is restricted, but the upper limit may be set to multiple times. This can be set appropriately depending on the expected number of balls per special lock effect.

The conditions for determining whether or not to execute the special lock effect are not limited to those described above. In other words, in the above, a mode transition is triggered by the winning of a "fixed role", and a determination is made as to whether or not to execute the special lock effect on the condition that the mode is Heaven C mode. However, since there may be cases where a transition to Heaven C mode is caused by factors other than the winning of a "fixed role" (see (f) in FIG. 8), a determination may be made as to whether or not to execute the special lock effect in these cases as well, and it may be determined that the special lock effect is executed with a predetermined probability (which may be the same probability as when the winning of a "fixed role" is the trigger, or may be a different probability).

For example, when a "guaranteed role" is won, a decision may first be made as to whether or not a special lock effect will be executed, and if it is decided that a special lock effect will be executed, a transition to Heaven C mode may occur. In other words, the special lock effect may be executed in response to a decision to transition to Heaven C mode, or a transition to Heaven C mode may be initiated in response to a decision to execute a special lock effect.

In addition, for example, the degree of progress of the game in the favorable zone may be used as a condition for determining whether or not the special lock effect is executed. For example, when the value of the favorable zone game number counter or the control game number counter described below is less than "750", or when the value of the favorable zone payout counter or the control payout number counter described below is less than "1201", the determination of whether or not the special lock effect is executed is made as described above, and when the value of the favorable zone game number counter or the control game number counter described below becomes "750" or more, or when the value of the favorable zone payout counter or the control payout number counter described below becomes "1201" or more, it is possible to prevent the determination of whether or not the special lock effect is executed in the same series of favorable zones thereafter.

In this way, in the first gaming machine, the play period of a series of advantageous zones is limited to a fixed period (see FIG. 16 described below). Furthermore, even if control information that is highly advantageous to the player (e.g., Heaven C mode) is set multiple times within the same series of advantageous zones, control is performed so that special effects (e.g., special lock effects) are not performed each time. Therefore, it is possible to prevent a decline in interest in the game while preventing the game from becoming excessively gambling-like.

In addition, in the first gaming machine, within a series of advantageous zones, the winning of a specific role (e.g., a "fixed role") may trigger control to be established in an advantageous state (e.g., a pseudo bonus), and control information that is highly advantageous to the player (e.g., Heaven C mode) may be set. Even if such an event occurs multiple times within the same series of advantageous zones, the machine is controlled so that a special effect (e.g., a special lock effect) is not performed each time. This makes it possible to prevent a decline in interest in the game while preventing the game from becoming excessively gambling-oriented.

The first gaming machine is also capable of determining secondary information (e.g., a sub-flag when a favorable zone is won) according to the determined internal winning role, and is also capable of determining secondary information (e.g., a sub-flag when a favorable zone is entered) according to the combination of symbols displayed, and is capable of determining whether or not to grant a favorable state (e.g., a pseudo bonus) in which information regarding the player's stopping operation is notified, according to the secondary information determined for each.

In this way, the first gaming machine can provide a sense of expectation regarding the award of an advantageous state not only when an internal winning combination is determined, but also when a combination of symbols is displayed, thereby diversifying the gameplay regarding the award of an advantageous state.

In addition, in the first gaming machine, both the information corresponding to the determined internal winning combination and the information corresponding to the displayed symbol combination are managed as common secondary information, so that it is possible to suppress an increase in the control load and amount of information related to the granting of an advantageous state.

In addition, in the first gaming machine, when the gaming value bet is a first amount (e.g., 3 coins), the first special role (e.g., 3BB) can be won, but the second special role (e.g., 2BB) cannot be won. In addition, when the gaming value bet is a second amount (e.g., 2 coins), the second special role can be won, but the first special role cannot be won. In addition, when a specific role (e.g., "F_Replay A") is won, if the first special permission state (e.g., between 3BB flags) is in effect, a combination of predetermined symbols (e.g., "Right-up replay") can be displayed, and if the second special permission state (e.g., between 2BB flags) is in effect, a combination of specific symbols (e.g., "Parallel replay") can be displayed (see FIG. 15 described below).

The first gaming machine is capable of determining different secondary information when a combination of predetermined symbols is displayed and when a combination of specific symbols is displayed. In other words, the first gaming machine can vary the content of the determination regarding the granting of an advantageous state depending on which special permission state is in effect, even when the same specific role is determined, and therefore can further diversify the gameplay while preventing an increase in the control load and amount of information regarding the granting of an advantageous state.

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

Here, in the first gaming machine, since the combination of the predetermined symbols and the combination of the specific symbols are both combinations of symbols related to replay, the same privilege of activating replay is awarded regardless of which one is displayed.

The manner in which the same benefit is awarded is not limited to the above. For example, the specific role is configured as a specific minor role related to the award of game value. Then, when the specific minor role is won, for example, in the first special permission state, a combination of predetermined patterns (a combination of patterns related to the award of game value equivalent to a "right-up lip") that awards a game value of one coin (this value is arbitrary and may be another value less than the bet game value, or may be a value exceeding the bet game value) is displayed, and in the second special permission state, a combination of specific patterns (a combination of patterns related to the award of game value equivalent to a "parallel lip") that awards the same number of game values as when the combination of predetermined patterns is displayed is displayed.

In addition, both the combination of the predetermined symbols and the combination of the specific symbols may be configured as "miss" symbol combinations (however, in order to be able to determine whether or not to grant an advantageous state, the combination of symbols must be identifiable as being different from a pure "miss" combination). Even in this case, the value remains the same.

In this way, in the first gaming machine, the decision content regarding the granting of an advantageous state can be varied depending on which special permission state is in place, even when the same specific role is determined, so that the gameplay can be diversified while suppressing an increase in the control load and amount of information regarding the granting of an advantageous state. Furthermore, in a game in which a specific role has been determined, the same benefit is granted regardless of which special permission state is in place, so that even when the gameplay is varied, it is possible to prevent the player from suffering a direct disadvantage.

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

In addition, it may be possible to determine whether or not to grant an advantageous state at least when a specific combination is won and a specific symbol combination is displayed. When a specific combination is determined as an internal winning role, it may be possible to make the degree of advantage regarding the granting of an advantageous state different between when a specific symbol combination is displayed and when a specific symbol combination is not displayed.

In addition, when a specific combination is won, if the first special permission state is established, a combination of specific symbols may be displayed regardless of the stop operation mode, and if the second special permission state is established, a combination of specific symbols may be displayed when the stop operation is performed in a specific mode, and a combination of specific symbols may be displayed when the stop operation is not performed in a specific mode.

In this case, the specific combination can be configured so that, on at least one reel, a specific symbol combination is displayed when the timing of the stopping operation is appropriate (in this embodiment, this may be described as "press position O" or "correct press position", etc.), and a predetermined symbol combination is displayed when the timing of the stopping operation is inappropriate (in this embodiment, this may be described as "press position X" or "incorrect press position", etc.). This allows the degree of advantage regarding the granting of an advantageous state to vary depending on the player's stopping operation (the timing), which allows the player to concentrate more on the game and increases the enjoyment of the game.

As mentioned above, the specific role can also be configured as a specific minor role. In this case, when the timing of the stop operation is appropriate (when the pressing position is ○), a specific combination of symbols is displayed and a specific number of game values is awarded on at least one reel, and when the timing of the stop operation is not appropriate (when the pressing position is ×), a specific combination of symbols is displayed and a specific number of game values is awarded. In this case, the specific number may be the same as the specific number (i.e., the same benefit). Also, the specific number may be awarded with a game value that is greater than the specific number. Also, the specific number may be awarded with a game value that is less than the specific number. Also, at least one of the specific combination of symbols and the specific combination of symbols may be the combination of symbols when a miss occurs. In other words, either the specific number or the specific number may be set to "0". This not only makes it possible to vary the degree of advantage in terms of granting an advantageous state based on the player's stopping operation (or the timing of that operation), but also makes it possible to vary the direct content of the bonus, allowing the player to concentrate more on the game, and further diversifying the gameplay, thereby increasing the interest of the game.

In addition, if there is only one type of specific role, the timing at which the timing of the stop operation is appropriate is also limited, so it is desirable to provide multiple specific roles with different timings at which the timing of the stop operation is appropriate. For example, in one reel, a first specific role is provided in which, when the timing of the stop operation is a first timing, the appropriate stop operation is performed and a combination of specific symbols is displayed, and when the timing is other than the first timing, the appropriate stop operation is not performed and the combination of specific symbols is not displayed; a second specific role is provided in which, when the timing of the stop operation is a second timing different from the first timing, the appropriate stop operation is performed and a combination of specific symbols is displayed, and when the timing is other than the second timing, the appropriate stop operation is not performed and the combination of specific symbols is not displayed; and a third specific role is provided in which, when the timing of the stop operation is a third timing different from the first timing and the second timing, the appropriate stop operation is performed and a combination of specific symbols is displayed, and when the timing is other than the third timing, the appropriate stop operation is not performed and the combination of specific symbols is not displayed, and these roles are set to win with the same probability of winning.

In this case, the special role can be configured so that a combination of specific symbols is displayed when the batting order is appropriate (when the button press order is correct), and a combination of predetermined symbols is displayed when the batting order is inappropriate (when the button press order is incorrect). This allows the degree of advantage in terms of the granting of an advantageous state to vary depending on the player's stopping operation (procedure), allowing the player to concentrate more on the game, and increasing the player's interest in the game.

The specific role can also be configured as a specific minor role as described above. In this case, when the batting order is appropriate (when the push order is correct), a specific combination of symbols is displayed and a specific number of game values is awarded, and when the batting order is not appropriate (when the push order is incorrect), a specific combination of symbols is displayed and a specific number of game values is awarded. In this case, the specific number may be the same as the specific number (i.e., the same benefit). The specific number may be awarded with a game value that is greater than the specific number. The specific number may be awarded with a game value that is less than the specific number. At least one of the specific combination of symbols and the specific combination of symbols may be the combination of symbols when a miss occurs. In other words, either the specific number or the specific number may be set to "0". This not only changes the degree of advantage regarding the award of an advantageous state due to the player's stopping operation (procedure), but also changes the content of the direct benefit, so that the player can concentrate more on the game, and the gameplay can be further diversified, thereby improving the interest of the game.

Also, if there is only one type of specific role, the appropriate batting order is also limited, so it is desirable to provide multiple specific roles with different appropriate batting orders. For example, a first specific role is provided in which, when the first stop is on the left, an appropriate stop operation is performed and a combination of specific symbols is displayed, and when the first stop is on the center or right, an appropriate stop operation is not performed and a combination of specific symbols is not displayed; a second specific role is provided in which, when the first stop is on the center, an appropriate stop operation is performed and a combination of specific symbols is displayed, and when the first stop is on the left or right, an appropriate stop operation is not performed and a combination of specific symbols is not displayed; and a third specific role is provided in which, when the first stop is on the right, an appropriate stop operation is performed and a combination of specific symbols is displayed, and when the first stop is on the left or center, an appropriate stop operation is not performed and a combination of specific symbols is not displayed, and these roles are set to win with the same probability of winning.

So far, we have mentioned that in a unit game in which a specific combination has been won, the process of determining whether a non-advantageous zone will transition to an advantageous zone and the process of determining whether an advantageous state will be granted in an advantageous zone (including pseudo bonus transition lotteries, mode transition lotteries, and other processes for changing the degree of advantage of the game situation in an advantageous zone) change due to the stop operation mode (at least one or both of the timing of the stop operation and the batting order). However, among such changes, any change that is relatively disadvantageous to the player (which may ultimately result in an disadvantage) can be considered as the above-mentioned penalty. Therefore, when such a change occurs, the configuration may be such that any presentation (warning notification) can be generated to call the player's attention.

In addition, in the first gaming machine, when a specific combination is won, the possibility of an advantageous state being granted is higher when a combination of specific symbols is displayed than when a combination of predetermined symbols is displayed. In other words, assuming that three coins are bet, the second special permission state (e.g., between 2BB flags) is a state in which the granting of an advantageous state is favored more than the first special permission state (e.g., between 3BB flags).

In addition, in the first gaming machine, when a predetermined role (for example, the "push order bell B" described below) is won, if the first special permission state is selected, the combination of symbols to be awarded (for example, a combination of symbols that will pay out 8 coins) is displayed regardless of the batting order, while if the second special permission state is selected, if the batting order is the predefined correct push order, the combination of symbols to be awarded is displayed, but if the batting order is not the predefined correct push order, the combination of symbols to be awarded is not displayed, resulting in a miss where no game value is awarded, or a combination of symbols to which less game value is awarded than when the combination of symbols to be awarded is displayed (for example, a combination of symbols that will pay out 1 coin) is displayed. In other words, if the operation of the advantageous state is not taken into consideration, the first special permission state is a state in which the award of game value is favored more than the second special permission state.

In other words, if a player plays in a 3-coin bet state between 3BB flags even in a non-recommended play state, the probability of obtaining an advantageous state is not favored, but the probability of obtaining a play value when an advantageous state is not activated is favored, so the player can play in a state where the difference in the slope value between when an advantageous state is activated and when it is not activated is relatively small. In this way, a state in which the player's play value is unlikely to decrease, although the possibility of the player being able to suddenly increase the play value, is reduced, can be defined as, for example, a "stable state."

On the other hand, if a player plays in the recommended game state, the probability of obtaining an advantageous state is favored, but the probability of obtaining game value when the advantageous state is not activated is not favored, so the player can play in a state where the difference in the slope value between when the advantageous state is activated and when it is not activated is relatively large. In this way, a state in which the player is more likely to be able to rapidly increase his or her game value, but in which the player's game value is likely to decrease, can be defined as, for example, a "rough seas state."

Here, the method of creating the two states, the stable state and the rough sea state, is not limited to the above. For example, in the "stable state", the transition probability of the pseudo bonus is increased in the pseudo bonus transition lottery described above compared to the "rough sea state", while the transition probability of the heaven mode is decreased in the mode transition lottery described above compared to the "rough sea state". Also, in the "rough sea state", the transition probability of the pseudo bonus is decreased in the pseudo bonus transition lottery described above compared to the "stable state", while the transition probability of the heaven mode is increased in the mode transition lottery described above compared to the "stable state". In this way, in the "stable state", a state can be created in which it is easy to hit the pseudo bonus for the first time, but difficult to win consecutive wins, and in the "rough sea state", a state can be created in which it is difficult to hit the pseudo bonus for the first time, but easy to win consecutive wins. As described above, the stop control of the predetermined role may vary between the 2BB flag and the 3BB flag, or may be different from this (i.e., not favoring the 3BB flag).

[5-2. Symbol Arrangement Configuration of First Gaming Machine]
Next, the symbol arrangement configuration of the first gaming machine will be described with reference to Fig. 9. 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, ten types of symbols, "red 7", "BAR", "replay", "bell", "watermelon", "cherry", "red blank", "yellow blank", "white blank 1" and "white blank 2", are arranged in the positions shown in Fig. 9 on each of the reels 3L, 3C and 3R. Also, as shown in the symbol code table, symbol codes 1 to 10 are assigned to each symbol.

[5-3. Internal lottery winning combination configuration of the first gaming machine]
Next, the internal winning combination configuration of the first gaming machine will be described with reference to Fig. 10 to Fig. 15. Fig. 10 is a diagram showing an example of an internal lottery table of the first gaming machine. Figs. 11 to 14 are diagrams showing an example of a symbol combination table of the first gaming machine. Fig. 15 is a diagram showing an example of a correspondence relationship between the internal winning combination, the stop operation mode, and the display combination, etc. of the first gaming machine.
In other words, the following will explain the types of internal winning roles drawn in the first gaming machine, and which combinations of patterns (which can also be referred to as display roles, winning roles, stop display modes, display results, etc.) are displayed depending on the stop operation mode (i.e., the hitting order, the timing of the stop operation, etc.) when each internal winning role is won.

First, in the first gaming machine, in the internal lottery process (see FIG. 26) described below, 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 permitted to be displayed when each internal winning combination is won are as shown in "Corresponding symbol combinations" in FIG. 10. Also, in FIGS. 11 to 14, "BB" indicates a symbol combination related to a bonus role, "REP" indicates a symbol combination related to a replay role, and "FRU" indicates a symbol combination related to a minor role.

"F_2BB" can be determined as an internal winning role when playing in a non-bonus state (more specifically, between non-flags) with 2 bets, but is configured not to be determined as an internal winning role when playing in a 3 bet state. In a game in which "F_2BB" wins in a 2 bet state or a game in which it is a "lose" between 2BB flags, if the pressed position for each reel is ○, "BB01" is displayed and the state transitions to 2BB state (bonus state based on 2BB). On the other hand, in a 3 bet state, even between 2BB flags, "BB01" is not displayed.

"F_3BB" can be determined as an internal winning role when a game is played in a non-bonus state (more specifically, between non-flags) with three bets, but is configured not to be determined as an internal winning role when a game is played in a two bet state. In a game in which "F_3BB" wins in a three bet state, or in a game in which a "lose" occurs between 3BB flags, if the pressed position is ○ for each reel, "BB02" is displayed and the game transitions to the 3BB state (bonus state based on 3BB). On the other hand, in a two bet state, even between 3BB flags, "BB02" is not displayed.

In the 2BB and 3BB states, the lottery value in the "bonus state" column in FIG. 10 is referenced to determine the internal winning combination (only three coins can be bet to start playing). In the 2BB and 3BB states, the RB, which is a first-class special combination, is always in operation (RB state). The RB state is repeatedly controlled to end once and then activate again if two wins occur or two games are played after it is activated. In the first gaming machine, the end condition for the 2BB state is stipulated as more than one medal being paid out in the 2BB state, and the end condition for the 3BB state is stipulated as more than 176 medals being paid out in the 3BB state.

Here, when the 2BB state or 3BB state ends, a special mode transition process is performed. For example, if the mode when transitioning to the bonus state (same as when the bonus state ends, since no mode transition occurs during the bonus state), i.e. the current mode, is "start mode", the mode to transition to will be "start mode". Also, if the current mode is either "normal A mode", "normal B mode", "heaven preparation mode", or "chance mode", the mode to transition to will be "normal A mode". Also, if the current mode is either "end A mode" or "end B mode", the mode to transition to will be "end A mode". Also, if the current mode is either "guaranteed mode", "heaven A mode", "heaven B mode", or "heaven C mode", the mode to transition to will be "guaranteed 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. When determined as an internal winning combination, between non-flags and 2BB flags, regardless of the stopping operation mode, any of "REP64" to "REP72" (these are collectively called "parallel reps" because they display the "replay" symbols in a straight line in the lower row or in the middle row. Also, "REP64" to "REP71" can be collectively called "lower row reps" and "REP72" can be called "middle row reps") is displayed, and a replay is awarded. On the other hand, between 3BB flags, regardless of the stopping operation mode, "REP73" (this is a replay symbol that displays the "replay" symbols in a straight line to the right, so it can be called a "right-up reps") is displayed, and a replay is awarded.

"F_Replay B" is configured to be determined as an internal winning role regardless of the number of bets in a non-bonus state. Note that while it can be determined as an internal winning role in a three-coin bet state, it can also be configured not to be determined as an internal winning role in a two-coin bet state. If it is determined as an internal winning role, a "parallel replay" is displayed regardless of the stop operation mode in either state, and a replay is granted.

In the non-bonus state, "F_Cherry" is configured to be determined as an internal winning role regardless of the number of bets. Note that while it can be determined as an internal winning role in the three-coin bet state, it can also be configured not to be determined as an internal winning role in the two-coin bet state. If it is determined as an internal winning role, in the two-coin bet state, a "middle row replay" is displayed regardless of the stop operation mode, and a replay is awarded. In the three-coin bet state, if the push position is ○ on at least the left reel 3L, any of "REP28", "REP60" to "REP63" (these can be collectively referred to as "cherry replays" since they display the "cherry" symbol in the lower row on the left reel 3L) is displayed, and a replay is awarded. On the other hand, if the push position is ×, other replays (for example, "REP57" to "REP59") are displayed, and a replay is awarded.

In the non-bonus state, "F_Definite Cherry" is configured to be determined as an internal winning role regardless of the number of bets. Note that, while it can be determined as an internal winning role in the three-coin bet state, it can also be configured not to be determined as an internal winning role in the two-coin bet state. If it is determined as an internal winning role, in the two-coin bet state, a "middle row replay" is displayed regardless of the stop operation mode, and a replay is awarded. In the three-coin bet state, if the pressing order is any of "batting order 1" to "batting order 4", any of "REP42" to "REP56" (these are used to display the "cherry" symbol in the lower row on the left reel 3L, and since symbols that can increase the player's expectations, such as "REP42", are also displayed on other reels), a replay is awarded. On the other hand, if the button is pressed at an X position, other replies (such as the above-mentioned "Cherry rep" or "REP29" to "REP41") are displayed and a replay is granted. Also, if the button is pressed in either "batting order 5" or "batting order 6", a "middle row rep" is displayed regardless of the stopping operation mode, and a replay is granted.

In the non-bonus state, "F_middle cherry" is configured to be determined as an internal winning role regardless of the number of bets. It can be configured so that it can be determined as an internal winning role in the three-coin bet state, but not determined as an internal winning role in the two-coin bet state. If it is determined as an internal winning role, in the two-coin bet state, a "middle lip" is displayed regardless of the stop operation mode, and a replay is awarded. In the three-coin bet state, if the push order is any of "batting order 1" to "batting order 4", if the push position is ○ for at least the left reel 3L, any of "REP15" to "REP19" (these are collectively referred to as "middle cherry lip" because they display the "cherry" symbol in the middle of the left reel 3L) is displayed, and a replay is awarded. On the other hand, if the push position is ×, other lips (for example, "REP20" to "REP27") are displayed, and a replay is awarded. Additionally, if the push order is either "batting order 5" or "batting order 6," a "middle lip" will be displayed regardless of the stopping operation mode, and a replay will be granted.

In the non-bonus state, "F_Reach Eye" is configured to be determined as an internal winning role regardless of the number of bets. Note that, although it can be determined as an internal winning role in the three-coin bet state, it can also be configured not to be determined as an internal winning role in the two-coin bet state. If it is determined as an internal winning role, in the two-coin bet state, a "middle lip" is displayed regardless of the stopping operation mode in the two-coin bet state, and a replay is awarded. In the three-coin bet state, if the push order is any of "batting order 1" to "batting order 4", any of "REP01" to "REP14" (these are configured as combinations of symbols that can, by convention, definitely notify (or suggest) a transition to a state that is advantageous to the player, and these can be collectively referred to as "Reach Eye Lip") is displayed regardless of the stopping operation mode, and a replay is awarded. Also, if the push order is any of "batting order 5" and "batting order 6", a "middle lip" is displayed regardless of the stopping operation mode, and a replay is awarded.

In a non-bonus state, "F_watermelon" is configured to be determined as an internal winning combination regardless of the number of bets. When determined as an internal winning combination, if the push position for each reel is ○, one of "FRU10" to "FRU12" (these are collectively called "watermelon" because they display "watermelon" symbols side by side) is displayed, and if three coins are bet, three medals are paid out, and if two coins are bet, two medals are paid out. On the other hand, if the push position is ×, one of "FRU08" and "FRU09" (these are collectively called "watermelon spill" because they do not display "watermelon" symbols side by side) is displayed, and one medal is paid out. Note that if the push position is ×, it can also be configured so that a spill occurs and zero medals are paid out.

"F_Bell 123A1", "F_Bell 123A2", "F_Bell 132A1", "F_Bell 132A2", "F_Bell 213A1", "F_Bell 213A2", "F_Bell 231A1", "F_Bell 231A2", "F_Bell 312A1", "F_Bell 312A2", "F_Bell 321A1", and "F_Bell 321A2" are configured to be determined as internal winning roles in a non-bonus state regardless of the number of bets. These can be collectively referred to as "Push Order Bell A".

As shown in FIG. 15, "Push Order Bell A" is a push order minor role with six options (one of "Batting Order 1" to "Batting Order 6" is the correct push order), and if it is determined as the internal winning role, and the stopping operation is performed in the corresponding correct push order, one of the following "bells" will be displayed: "Downward Right Bell" ("FRU03"), "Top Row Bell" ("FRU01" and "FRU02"), "Middle Row Bell" ("FRU04"), "Upward Right Bell" ("FRU05"), "Small Hill Bell" ("FRU06"), and "Bottom Row Bell" ("FRU07"). If three coins are bet, eight medals will be paid out, and if two coins are bet, two medals will be 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, there is a 1/2 probability that the remaining stop operations will have a press position of ○, and if the press position is ○, one of the winning "1 coin roles" ("FRU13" to "FRU116") will be displayed, and one medal will be paid out. On the other hand, if the press position is ×, a miss will occur and no medal will be paid out. Also, if the first stop operation is incorrect, there is a 1/8 probability that the remaining stop operations will have a press position of ○, and if the press position is ○, one of the winning "1 coin roles" ("FRU13" to "FRU116") will be displayed, and one medal will be paid out. On the other hand, if the press position is ×, a miss will occur and no medal will be paid out.

"F_Bell 123B1", "F_Bell 123B2", "F_Bell 132B1", "F_Bell 132B2", "F_Bell 213B1", "F_Bell 213B2", "F_Bell 231B1", "F_Bell 231B2", "F_Bell 312B1", "F_Bell 312B2", "F_Bell 321B1", and "F_Bell 321B2" are configured to be determined as internal winning roles in a non-bonus state regardless of the number of bets. These can be collectively referred to as "Push Order Bell B".

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

As shown in FIG. 15, the "Push Order Bell B" is a push order minor role in states other than between 3BB flags in the 3-coin bet state (between non-flags in the 3-coin bet state, between 2BB flags in the 3-coin bet state), and when it is determined as an internal winning role, if the stop operation is performed in the corresponding correct push order, one of the above-mentioned "bells" is displayed and 8 medals are paid out. On the other hand, if the stop operation is not performed in the corresponding correct push order, if the first stop operation is correct, the remaining stop operation will have a 1/2 probability of being a push position O, and if the push position is O, one of the winning "1-coin roles" will be displayed and one medal will be paid out. On the other hand, if the push position is X, a miss will occur and no medal will be paid out. Also, if the first stop operation is incorrect, the remaining stop operation will have a 1/8 probability of being a push position O, and if the push position is O, one of the winning "1-coin roles" will be displayed and one medal will be paid out. On the other hand, if the push position is X, a miss will occur and no medal will be paid out.

The "8 F_RB" is configured to be determined as an internal winning role in the bonus state. If it is determined as an internal winning role, one of the "bells" described above will be displayed regardless of the stopping operation mode, and 8 medals will be paid out.

The "F_RB 1 coin" is configured to be determined as an internal winning role in the bonus state. When determined as an internal winning role, any of the above-mentioned "1 coin roles" (more specifically, "FRU117" to "FRU120" are added) is displayed regardless of the stop operation mode, and one medal is paid out.

Note that the internal lottery table shown in FIG. 10, the symbol combination tables shown in FIG. 11 to FIG. 14, and the correspondence between the internal winning combinations, stop operation modes, and display combinations shown in FIG. 15 are merely examples, and are not limited to the modes shown here.

For example, in the first gaming machine, a "miss" may occur in various situations, such as when there is a pure "miss"; when in a 2-bet state where "BB01" can be displayed, "BB01" is missed and becomes a "miss"; when in a 3-bet state where "BB02" can be displayed, "miss" occurs when "BB02" is missed and becomes a "miss"; when there is a 3-bet state between 2BB flags; when there is a 2-bet state between 3BB flags; when there is a "miss" when "push order minor role" is missed and becomes a "miss". Therefore, in order to change the combination of symbols displayed as a "miss" in some or all of these cases, these different combinations of symbols are specified in advance in a symbol combination table, and these are allowed to be displayed as "corresponding symbol combinations" depending on the determined internal winning role, so that the combination of symbols related to the "miss" displayed can be changed depending on the situation, etc.

[5-4. Limit processing configuration of the first gaming machine]
Next, the limit processing configuration of the first gaming machine will be described with reference to FIG. 16. FIG. 16 is a diagram for explaining an example of each limit processing in the first gaming machine. As shown in FIG. 16, in the first gaming machine, each limit processing of 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 (number of games), and semi-limit processing (number of payouts) is executed. Note that this is an example of executable limit processing, and limit processing other than each of these limit processings can be executed, or some of these limit processings can be prevented from being executed.

Normal limit processing (number of games) is executed when the value of the advantageous zone game number counter reaches 1500 or more (i.e., when 1500 consecutive plays have been played during the advantageous zone). The advantageous zone game number counter starts counting the number of plays when the advantageous zone (including the presentation zone) starts, and ends and is cleared (initialized) when the advantageous zone ends (including the end due to the operation of the limit processing). The advantageous zone game number counter also counts when the number of bets is either 2 or 3 coins. The advantageous zone game number counter also counts in the 2BB and 3BB states.

When the normal limit process (number of games) is executed (activated), regardless of whether it is during the presentation period or the increase period (pseudo bonus), the advantageous period is forcibly ended and transitioned to a non-advantageous period. At this time, all information related to the advantageous period (for example, information for controlling the presentation period or increase period, information related to the current mode, information related to the play period of the pseudo bonus, information related to the ceiling game number and whether the ceiling has been shortened, the value of the 1G consecutive stock counter, and various information obtained during the advantageous period and various information required to control the advantageous period) is also cleared (initialized).

Normal limit processing (number of payouts) is executed when the value of the favorable zone payout counter becomes "2401" or more (i.e., when the number of medals paid out during the favorable zone exceeds 2400). The favorable zone payout counter starts counting the number of medals paid out (here, for example, the "net increase (difference)") when the favorable zone (including the performance zone) starts, and ends the counting and is cleared (initialized) when the favorable zone ends (including the end due to the operation of the limit processing). The favorable zone payout counter also counts when the number of bets is 2 or 3. The favorable zone payout counter also counts in the 2BB state and the 3BB state. The favorable zone payout counter also subtracts a value that is appropriately counted according to the actual payout number (for example, "-2" or "-3") when a "miss" or "miss" occurs during the favorable zone. Therefore, in cases where the number of medals does not increase but decreases after the start of the favorable zone, the value may become negative (or it may be configured to always remain "0" when the value becomes negative). In other words, the favorable zone payout number counter is capable of counting from the lowest point of the number of medals paid out during the favorable zone to the defined highest point (difference in number of medals: 2400 medals).

When the normal limit process (payout amount) is executed (activated), regardless of whether the player is in the performance period or the increase period (pseudo bonus), the advantageous period is forcibly ended and the player transitions to a non-advantageous period. At this time, all information related to the advantageous period 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 (i.e., when 1445 consecutive plays have been played during the favorable zone). The control game number counter starts counting the number of plays when the favorable zone (including the presentation zone) starts, and ends and is cleared (initialized) when the favorable zone ends (including the end due to the operation of the limit process). The control game number counter counts when the number of bets is three coins, and does not count when the number of bets is two coins. The control game number counter counts when in a non-bonus state, and does not count when in a 2BB state or a 3BB state. However, the control game number counter can also be configured in the same way as the favorable zone game number counter.

When the special limit process (number of games) is executed (activated), if the pseudo bonus is in progress (i.e., during an increase period), the pseudo bonus is not forcibly ended midway, but when the pseudo bonus ends, the advantageous period is forcibly ended accordingly and a transition is made to a non-advantageous period. At this time, all information related to the aforementioned advantageous period is also cleared (initialized).

On the other hand, if the player is not in a pseudo bonus (i.e., during the presentation period), the game will first forcibly transition to the pseudo bonus. In other words, even if the pseudo bonus transition lottery is not won, the game will transition to the pseudo bonus by executing this special limit process (number of games). Then, when the pseudo bonus to which the player has transitioned ends, the advantageous period will be forcibly ended accordingly, and the game will transition to a non-advantageous period. At this time, all information regarding the advantageous period described above will also be cleared (initialized).

Note here that the value of the advantageous zone game number counter where normal limit processing (number of games) is executed (activated) is "1500", while the value of the control game number counter where special limit processing (number of games) is executed (activated) is "1445". Since the maximum number of games played (continuation period) during a pseudo bonus is "55 games" in the first gaming machine (see Figure 5), this difference takes into account the playable period during a pseudo bonus.

In other words, the normal limit process (number of games) is executed when a predetermined restricted period of play has been played in the advantageous zone in order to prevent the gambling nature of the game from becoming too high. However, for example, if this normal limit process (number of games) is executed immediately after the pseudo bonus starts or during it, the player may feel distrust or a sense of loss, which may reduce interest in the game. Therefore, in the first gaming machine, the special limit process (number of games) is executed in a game that is one possible continuation period (55 games) per increased zone before the game in which the normal limit process (number of games) is executed, thereby preventing the pseudo bonus from ending prematurely and causing the player to feel distrust or a sense of loss.

From this viewpoint, the timing at which the special limit process (number of games) is executed (operated) is not limited to the above. For example, the special limit process (number of games) may be executed in a game that is two increase intervals earlier than the game in which the normal limit process (number of games) is executed, by a continuation possible period (55 games x 2 sets = 110 games).
Also, for example, in order to provide a slight grace period, the special limit processing (number of games) may be executed in a game that is a continuation possible period (55 games) per increased section plus the grace period (2 games) before the game in which the normal limit processing (number of games) is executed. Also, for example, in the case of a specification in which a premonition state is passed through before a transition to a pseudo bonus, and the maximum number of games in this premonition state is "4 games", the special limit processing (number of games) may be executed in a game that is a continuation possible period (55 games) per increased section plus the maximum premonition period (4 games) before the game in which the normal limit processing (number of games) is executed. In other words, the timing at which the special limit processing (number of games) is executed (operated) may be any timing as long as it is a timing before the timing at which the normal limit processing (number of games) is executed, and may be set appropriately according to individual game specifications, etc.

The special limit process (payout number) is executed when the value of the control payout number counter becomes "2126" or more (i.e., when the number of medals paid out during the favorable period exceeds 2125). The control payout number counter starts counting the number of medals paid out (here, for example, "net increase (difference in number of medals)") from the start of the favorable period (including the performance period), and ends the counting and is cleared (initialized) when the favorable period ends (including the end due to the operation of the limit process). The control payout number counter also counts when the number of bets is 3, and does not count when the number of bets is 2. The control payout number counter also counts when in a non-bonus state, and does not count when in a 2BB state or a 3BB state.

In addition, when a "miss" occurs during a favorable zone, the control payout counter subtracts an appropriate count value according to the actual number of medals paid out (for example, "-3 medals"). However, when a "miss" occurs during a favorable zone (at least when a difference occurs from the maximum number of medals paid out), the control payout counter counts the number of medals paid out as if no "miss" (or difference) occurred. Specifically, for example, in a game where you bet three coins and win "Push Order Bell A," if the stroke order is correct, the number of medals paid out (maximum) will be "8 medals" (the difference in number is "+5 medals"), but if the stroke order is not correct and the pressing position is correct, the number of medals paid out will be "1 medal" (the difference in number is "-2 medals"), and if the pressing position is not correct, a missed medal will occur and the number of medals paid out will be "0 medals" (the difference in number is "-3 medals"); however, the control payout counter will count the difference in number of medals as "+5 medals" in either case in that game.

In addition, for example, if the value of the advantageous zone payout number counter becomes greater than the value of the control payout number counter due to the activation of the 2BB state or 3BB state, the value of the control payout number counter is corrected to the value of the advantageous zone payout number counter. The control payout number counter can also be configured in the same way as the advantageous zone payout number counter.

When the special limit process (payout amount) is executed (activated), if the pseudo bonus is in progress (i.e., during an increase period), the pseudo bonus is not forcibly ended midway, but when the pseudo bonus ends, the advantageous period is forcibly ended accordingly and a transition is made to a non-advantageous period. At this time, all information related to the aforementioned advantageous period is also cleared (initialized).

On the other hand, if the player is not in a pseudo bonus (i.e., during the presentation period), the game will first forcibly transition to the pseudo bonus. In other words, even if the pseudo bonus transition lottery is not won, the game will transition to the pseudo bonus by executing this special limit process (payout number). Then, when the pseudo bonus to which the game has been transitioned ends, the advantageous period will be forcibly ended accordingly, and the game will transition to a non-advantageous period. At this time, all information relating to the advantageous period described above will also be cleared (initialized).

Note that the value of the advantageous zone payout counter where normal limit processing (payout amount) is executed (activated) is "2401", while the value of the control game number counter where special limit processing (payout amount) is executed (activated) is "2126". Since the maximum number of coins that can be won during a pseudo bonus (amount of game value that can be awarded) in the first gaming machine is "275 coins" (see Figure 5), this difference takes into account the amount of game value that can be awarded during a pseudo bonus.

In other words, the normal limit process (payout number) is executed when a game value equivalent to a predetermined regulated game value amount is awarded in the advantageous zone in order to prevent the game from becoming too gambling-like. However, for example, if this normal limit process (payout number) is executed immediately after the start of a pseudo bonus or during it, the player may feel distrust or a sense of loss, and their interest in the game may decrease. Therefore, in the first gaming machine, the special limit process (payout number) is executed when a game value amount that is awarded is less than the game value amount at which the normal limit process (payout number) is executed by the amount of game value that can be awarded per increased zone (275 coins), thereby preventing the pseudo bonus from ending midway and causing the player to feel distrust or a sense of loss.

From this perspective, the timing at which the special limit process (payout number) is executed (operated) is not limited to the above. For example, the special limit process (payout number) may be executed when a game value amount that is less than the game value amount at which the normal limit process (payout number) is executed is awarded by the amount of game value that can be awarded per two increase sections (275 pieces x 2 sets = 550 pieces). Also, for example, in order to provide a slight grace period, the special limit process (number of games) may be executed when a game value amount that is less than the game value amount at which the normal limit process (payout number) is executed is awarded by the amount of game value that can be awarded per one increase section (275 pieces) + the amount of game value equivalent to the grace period (8 pieces). In other words, the timing at which the special limit process (payout number) is executed (operated) may be any timing before the timing at which the normal limit process (payout number) is executed, and can be set appropriately according to individual game specifications, etc.

The semi-limit process (number of games) is executed when the value of the control game number counter is added to the value of the 1G consecutive counter (if the ceiling shortening lottery is won and the result is "ceiling shortening enabled", then "1" is added) multiplied by "55" (i.e., the period during which the pseudo bonus can continue), and the result of the addition is "1390" or more. For example, if the value of the 1G consecutive counter is "1" and "ceiling shortening enabled", then the latter value is "55 x 2 = 110", so the semi-limit process (number of games) is executed (activated) when the value of the control game number counter is "1280".

The semi-limit process (payout number) is executed when the value of the control payout number counter is added to the value of the 1G consecutive counter (if the ceiling shortening lottery is won and the ceiling shortening lottery is set to "ceiling shortening enabled", then "1" is added) multiplied by "275" (i.e., the amount of game value that can be awarded with the pseudo bonus), and the result of the addition is "1851" or more. For example, if the value of the 1G consecutive counter is "1" and the ceiling shortening is enabled, then the latter value is "275 x 2 = 550", so the semi-limit process (payout number) is executed (operated) when the value of the control payout number counter is "1301". Note that since the semi-limit process (number of games) and the semi-limit process (payout number) both perform the same restriction, once the operating condition of one is met and activated, there is no need to operate it redundantly even if the operating condition of the other is met.

When the semi-limit process (number of games) or the preparation limit process (number of payouts) is executed (activated), the above-mentioned 1G consecutive lottery and ceiling shortening lottery are not executed during the pseudo bonus in the subsequent series of advantageous zones. In other words, the extension of the play period in the increase zone is suppressed. Note that the method of suppressing the extension of the play period in the increase zone is not limited to this. For example, in the above-mentioned 1G consecutive lottery, the winning probability of 1G consecutive may be made lower than normal, and in the above-mentioned ceiling shortening lottery, the winning probability of ceiling shortening may be made lower than normal. In other words, the above-mentioned 1G consecutive lottery and ceiling shortening lottery themselves are executed, but it may be made difficult to win these lotteries. Also, for example, in the performance zone after the execution of the semi-limit process (number of games), the lottery value that will be a winning lottery in the pseudo bonus transition lottery may be lowered to make it difficult to transition to the pseudo bonus. Alternatively, the lottery value that determines a mode transition that is advantageous to the player in the mode transition lottery may be lowered, making it more difficult for the pseudo bonus to be consecutive.

In addition, when the semi-limit process (number of games) or semi-limit process (number of payouts) is executed (activated), in the series of subsequent advantageous periods, during the presentation period, special processing is performed when a "fixed role" (see FIG. 7(a)) is drawn. Below, this special processing is explained using the example of the case where the "fixed role" is "F_fixed cherry" (hereinafter sometimes simply referred to as "fixed cherry").

When neither the semi-limit process (number of games) nor the semi-limit process (number of payouts) is in operation, if a "Definite Cherry" is drawn during the presentation period (or during the increase period), a "Winning Lottery (Next Play)" is determined in the pseudo-bonus transition lottery (see FIG. 7(c)). In addition, in the first gaming machine, the "cherry" symbol on the left reel 3L is a symbol that players have high expectations for, so in a game in which information on the stop operation is not notified, the general procedure is for the player to perform a stop operation at the first left stop and while aiming for the "cherry" symbol (aiming for the "BAR" symbol as a guide). Therefore, when playing according to the general procedure, when a "Definite Cherry" is drawn, the "cherry" symbol is first stopped on the lower row of the left reel 3L at the first left stop. In addition, when neither the semi-limit process (number of games) nor the semi-limit process (number of payouts) is in operation, if a "fixed cherry" is drawn, a notification may be made to the effect that the first left stop ("batting order 1" and "batting order 2") should be made. In addition, a "winning lottery (next game)" is not limited to a lottery in which the pseudo bonus starts from the next game, and may be a lottery in which the pseudo bonus starts from the next game or later.

Here, a skilled player will perform a stopping operation, for example, aiming for the "BAR" symbol on the center reel 3C and right reel 3R, in order to further determine whether it is a "weak cherry" or a "definite cherry". As a result, the "BAR" symbols will line up in the middle of each reel, and the player will be able to recognize that they have won a "definite cherry" (see, for example, "REP42" in FIG. 11). On the other hand, a player without skill may not perform a stopping operation aiming for the "BAR" symbol on the center reel 3C and right reel 3R, or may be unable to perform such an operation, and may not be able to determine whether it is a "weak cherry" or a "definite cherry" from the stop display mode (see, for example, "REP28" in FIG. 11).

In the first gaming machine, when neither the semi-limit process (number of games) nor the semi-limit process (number of payouts) is operating, if a "determined cherry" is won and the symbol combination of a "determined cherry replay" is displayed, a special winning sound is output. Also, if a "determined cherry" is won and the symbol combination of a "determined cherry replay" is not displayed, but the symbol combination of a "cherry replay" is displayed, a special winning sound is 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, if you win a "Confirmed Cherry" when neither the semi-limit process (number of games) nor the semi-limit process (number of payouts) is in operation, you will be notified that a pseudo bonus will begin when the next game starts with a "Red 7s lined up" effect, and the pseudo bonus will begin.

On the other hand, if a "confirmed cherry" is drawn during the presentation period (or during the increase period) after either the semi-limit process (number of games) or the semi-limit process (number of payouts) has been activated, the pseudo-bonus transition lottery will initially determine "winning lottery (next game)" (see FIG. 7(c)), but this determination result will be rewritten to "winning lottery (current game)" by executing a special process. Then, at the start of the current game, a "red 7s line up" presentation will be performed to announce that a pseudo-bonus will begin, and the pseudo-bonus will begin.

At this time, in the current game, the symbol combination of "Determined Cherry Lip" (including the symbol combination of "Cherry Lip") is not displayed, and a notification (special notification) of information on the stop operation to display the symbol combination of "Middle Lip" is made. For example, in the first gaming machine, a special notification is made 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 process (number of games) nor the semi-limit process (number of payouts) is activated, the game flow is changed to "Determined Cherry Lip" display → pseudo bonus start from the next game, but after the activation of either the semi-limit process (number of games) or the semi-limit process (number of payouts), the game flow is changed to "middle lip" display by performing a stop operation according to the special notification from the current game. The special notification may be controlled by the main (main control board 71) side, or it may be controlled only by the sub (sub control board 72) side, from the viewpoint that the player will not suffer any disadvantage even if the result is a transition to a pseudo bonus.

In addition, if a "Definite Cherry" is won after either the semi-limit process (number of games) or the semi-limit process (number of payouts) has been activated, and the symbol combination for the "Definite Cherry Rep" is displayed despite a special notification being issued, the special winning sound will not be output.

In addition, in the first gaming machine, when "F_Replay A" or "F_Replay B" is determined as the internal winning role, the procedure for the stop operation is not basically notified. For this reason, if the procedure for the stop operation is notified and the "middle replay" is displayed only when the above-mentioned special notification is performed, when such a state occurs, the player will clearly recognize that one of the semi-limit processes has been activated, which may result in a decrease in interest in the game. Therefore, during the advantageous zone, regardless of whether or not one of the semi-limit processes is activated (or even after the activation of one of the semi-limit processes), if "F_Replay A" or "F_Replay B" is determined as the internal winning role, 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 that the special notification is unnatural. Also, when "F_Replay A" or "F_Replay B" is determined as the internal winning combination, a notification similar to the special notification may be made when the pseudo bonus transition lottery is won. Also, in this case, in the pseudo bonus transition lottery when "F_Replay A" or "F_Replay B" is determined as the internal winning combination, a "winning lottery (current game)" may be determined with a predetermined probability.

So far, we have used the example of monitoring the play period in the favorable zone using the "number of games" and "number of payouts" to activate the normal limit process, special limit process, and semi-limit process, but the conditions for executing each limit process are not limited to those described above and can be changed as appropriate. For example, the value of the favorable zone game number counter, the value of the favorable zone payout counter, the value of the control game number counter, the value of the control payout counter, as well as the value of the 1G consecutive counter and the presence or absence of ceiling shortening (i.e., variables for activating the semi-limit process), etc., when each limit process is executed, can be changed as appropriate depending on the game specifications, market trends, etc.

Furthermore, the method for monitoring the play period of the advantageous zone is not limited to the above. For example, if the "number of navigations" is used to monitor the play period of the advantageous zone, normal limit processing (number of navigations), special limit processing (number of navigations), or semi-limit processing (number of navigations) can be executed in the same manner as described above. In other words, any element (parameter) whose value can be counted can be adopted to monitor the play period of the advantageous zone, and by specifying the value at which normal limit processing is executed, the value at which special limit processing is executed, and the value at which semi-limit processing is executed for the adopted element, each limit processing can be executed in the same manner as described above.

As described above, in the first gaming machine, the advantageous state (e.g., pseudo bonus) and the specific state (e.g., presentation zone) are controlled as a series of advantageous zones, and when the play period in the series of advantageous zones becomes a predetermined period (e.g., the value of the advantageous zone game number counter is "1500" or more), or when the amount of game value granted in the series of advantageous zones becomes a predetermined amount (e.g., the value of the advantageous zone payout number counter is "2401" or more), the series of advantageous zones are forcibly ended. However, when the play period in the series of advantageous zones becomes a specific period shorter than the predetermined period (e.g., the value of the control game number counter is "1445" or more), or when the amount of game value granted in the series of advantageous zones becomes a specific amount less than the predetermined amount (e.g., the value of the control payout number counter is "2126" or more), if the advantageous state exists, the series of advantageous zones are ended when transitioning to the specific state.

In other words, in the first gaming machine, a series of advantageous periods is not forcibly ended in the middle of an advantageous state, but rather it is possible for a series of advantageous periods to end within a certain period in a natural flow that accompanies the end of an advantageous state. This makes it possible to prevent the player from feeling distrust or a sense of loss while suppressing excessive gambling, and therefore makes it possible to take into consideration the feelings of the player.

In addition, in the first gaming machine, the advantageous state (e.g., pseudo bonus) and the specific state (e.g., presentation zone) are controlled as a series of advantageous zones, and when the play period in this series of advantageous zones becomes a predetermined period (e.g., the value of the advantageous zone game number counter is "1500" or more), or when the amount of game value granted in this series of advantageous zones becomes a predetermined amount (e.g., the value of the advantageous zone payout counter is "2401" or more), this series of advantageous zones is forcibly ended, but when the play period in this series of advantageous zones becomes a specific period shorter than the predetermined period (e.g., the value of the control game number counter is "1445" or more), or when the amount of game value granted in this series of advantageous zones becomes a specific amount less than the predetermined amount (e.g., the value of the control payout counter is "2126" or more), if the advantageous state is not in effect, the advantageous state is transitioned to, and when the transitioned advantageous state ends and transition occurs to the specific state, the series of advantageous zones is terminated.

In other words, in the first gaming machine, a series of advantageous zones are not forcibly ended in the middle of an advantageous state, and it is possible to end a series of advantageous zones within a certain period of time in a natural flow that accompanies the end of an advantageous state. Furthermore, when ending a series of advantageous zones in this way, if the state is not advantageous, the system transitions to an advantageous state before ending the series. This makes it possible to prevent the player from feeling distrust or a sense of loss while suppressing excessive gambling, and therefore makes it possible to take into consideration the feelings of the player.

In addition, in the first gaming machine, the specific period or specific amount is set taking into consideration the period during which the advantageous state can continue (e.g., "55 games") or the amount of gaming value that can be awarded (e.g., "275 coins"), so that it is possible to prevent the amount of gaming value awarded to the player from being excessively restricted while still taking into consideration the feelings of the player.

In addition, in the first gaming machine, the advantageous state may be extended by the granted rights (for example, "1G consecutive stock" and "ceiling shortening"), but when the play period in a series of advantageous zones is shorter than the specific period and becomes a special period set according to the number of granted rights (for example, when the value of the control game number counter becomes a value at which the semi-limit process (number of games) is executed), or when the amount of game value granted in a series of advantageous zones is less than the specific amount and becomes a special amount set according to the number of granted rights (for example, when the value of the control payout number counter becomes a value at which the semi-limit process (payout number) is executed), the granting of rights is suppressed in the series of subsequent advantageous zones. This prevents, for example, a player from being granted more rights than he or she can consume, which would result in the series of advantageous zones being forcibly ended in such a state, causing the player to feel distrustful or have a sense of loss, and thus makes it possible to suppress excessive gambling while also taking into consideration the player's feelings.

In addition, in the first gaming machine, when counting the above-mentioned "specific amount" and "special amount," even if a difference occurs between the amount of game value that should have been awarded and the amount of game value that has actually been awarded due to, for example, a player's operating error or ignoring of instructions, this difference is not taken into consideration, and the calculation is performed based on the amount of game value that should have been awarded. This makes it possible to prevent a series of advantageous zones from being unnecessarily extended due to such player actions, and to prevent unfairness from occurring between players who have performed such actions and players who have not, making it possible to take into consideration the feelings of the player while preventing excessive speculation.

In addition, in the first gaming machine, when a fixed combination (e.g., "fixed cherry") that confirms a transition to an advantageous state is won in a state in which the granting of rights is suppressed (e.g., a state after the semi-limit processing has been activated), a special notification is made to prevent the display of a special pattern combination (e.g., "fixed cherry replay") that clearly indicates the winning of this fixed combination. This makes it possible to prevent the player from feeling that the winning of the fixed combination was a wasted win, for example. In other words, by preventing the player from clearly recognizing the trigger that started the advantageous state in a state in which the granting of rights is suppressed, it is possible to prevent excessive gambling while also taking into consideration the player's feelings. Note that any performance execution means may be used to make the special notification.

In addition, in the first gaming machine, when a special notification is made, the advantageous state that would have started from the next game is started from the current game. This allows the player to perform the stopping operation in accordance with the special notification in a natural flow, so that even when such a special notification is made, it is possible to prevent the player from feeling uncomfortable.

In addition, in the first gaming machine, when the granting of rights is not suppressed, if a fixed combination is won and a combination of special symbols is displayed, it is possible to issue a special notification (for example, output of a special winning sound), but when the granting of rights is suppressed, if a fixed combination is won and a combination of special symbols is displayed, it is not possible to issue a special notification. This makes it possible to prevent the player from feeling that the winning of the fixed combination was a wasted win, for example. In other words, by not allowing the player to clearly recognize the trigger that started the advantageous state when the granting of rights is suppressed, it is possible to prevent excessive gambling while also taking into consideration the player's feelings. Note that any performance execution means may be used to issue the special notification.

In addition, in the first gaming machine, the decision as to whether or not to issue a special notification is made depending on whether or not a fixed combination has been won, whether or not a special symbol combination has been displayed, and whether or not a special notification has been issued. This allows for more appropriate management of the circumstances under which a special notification is issued.

In addition, in the first gaming machine, the advantageous zone game number counter and advantageous zone payout number counter count regardless of the amount of gaming value bet, making it possible to execute normal limit processing (number of games) and normal limit processing (number of payouts) not only in the three-coin bet state but also in the two-coin bet state.

In addition, in the first gaming machine, the control game number counter and the control payout number counter perform counting in the three-coin bet state, but do not perform counting in the two-coin bet state. Therefore, in the three-coin bet state, it is possible for the special limit process (number of games) and special limit process (number of payouts) to be executed, but in the two-coin bet state, it is not possible for the special limit process (number of games) and special limit process (number of payouts) to be executed. Therefore, in the two-coin bet state, the execution of the normal limit process (number of games) or normal limit process (number of payouts) may forcibly end a series of advantageous periods even during a pseudo bonus.

In the first gaming machine, for example, the probability of winning the minor prize and the number of medals paid out differ between the three-coin bet state and the two-coin bet state (see Figures 10 to 15), so playing in the two-coin bet state is more disadvantageous to the player than playing in the three-coin bet state. However, the method of making playing in the two-coin bet state more disadvantageous to the player is not limited to this. For example, if playing in the two-coin bet state during a pseudo bonus is played, the stopping operation procedure may be notified so that the player is at a disadvantage.

In this way, in the first gaming machine, when a first amount (e.g., "3 coins") of gaming value is bet and play is performed, a series of advantageous periods are not forcibly ended in the middle of an advantageous state, and it is possible to end a series of advantageous periods within a certain period in a natural flow accompanying the end of an advantageous state. This makes it possible to prevent the player from feeling distrust or a sense of loss while suppressing excessively high gambling tendency, and therefore makes it possible to take into consideration the emotions of the player. On the other hand, when a second amount (e.g., "2 coins") of gaming value is bet and play is performed, a series of advantageous periods may be forcibly ended in the middle of an advantageous state, which makes it possible to make the player realize that he/she has not played in the intended playing method, and therefore encourages the player to play in the intended playing method.

In addition, since in a series of advantageous zones, when the second amount of game value is bet and play is performed, it is more disadvantageous for the player than when the first amount of game value is bet and play is performed, by making it possible to issue such a warning, it is possible to encourage the player to play in a more advantageous state, and it is possible to prevent a decrease in the interest of the game due to playing in a way that the player did not intend.

[5-5. Storage Area Configuration of First Gaming Machine]
Next, the configuration of the storage areas of the first gaming machine will be described with reference to Figs. 17 to 22. Fig. 17 is a diagram showing an example of a winning flag storage area, a winning activation flag storage area, and a symbol code storage area of the first gaming machine. Fig. 18 is a diagram showing an example of a carryover role storage area of the first gaming machine. Fig. 19 is a diagram showing an example of a game status flag storage area of the first gaming machine. Fig. 20 is a diagram showing an example of a mode flag storage area of the first gaming machine. Fig. 21 is a diagram showing an example of an activation stop button storage area of the first gaming machine. Fig. 22 is a diagram showing an example of a push order storage area of the first gaming machine.

(Winning lottery flag storage area, winning activation flag storage area, and pattern code storage area)
First, the configurations of the winning flag storage area (internal winning combination storage area), the winning activation flag storage area (display combination storage area), and the symbol code storage area will be described with reference to Fig. 17. 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 above storage areas is composed of storage areas 1 to 26, each represented by 1 byte of data. Note that the data stored in each storage area is only the 1 byte of data in the "Data" column in Figure 17, but for ease of explanation, Figure 17 also shows the "combination" (in Figure 17, the symbols on reel 3L, reel 3C, and reel 3R are listed in that order) indicating the symbol combination associated with the bit of each storage area, and its contents (see Figures 11 to 14).

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

The data stored in the winning activation flag storage area is used by the main CPU 101 to enable the type of symbol combination corresponding to the displayed role (i.e., the type of symbol combination displayed on the winning line in the current game). For example, if a symbol combination related to 2BB is displayed on the winning line in the current game, a "1" is stored in bit 0 of storage area 1.

The data stored in the symbol code storage area is used by the main CPU 101 to enable the main CPU 101 to identify the type of symbol combination that can still be displayed on an active line in the current game while at least one of the reels is spinning. For example, if a symbol combination related to 2BB can still be displayed on an active line while at least one of the reels is spinning in the current game, then "1" is stored in bit 0 of storage area 1.

(Carryover role storage area)
Next, the configuration of the carryover combination storage area will be described with reference to Fig. 18. The carryover combination storage area is configured with a storage area represented by 1-byte data.

When the internal lottery process determines that the bonus role of "F_2BB" (2BB) or "F_3BB" (3BB) is the internal winning role, these bonus roles are stored in the carryover role storage area as carryover roles ("1" is stored in the corresponding bit). The carryover roles stored in the carryover role storage area are not cleared and are retained until the corresponding symbol combination is displayed on the winning line. Also, while the carryover role is stored in the carryover role storage area, the carryover role (bonus role) is stored in the winning flag storage area in addition to the internal winning role (minor role/replay role) determined by the internal lottery process.

(Game Status Flag Storage Area)
Next, the configuration of the game status flag storage area will be described with reference to Fig. 19. The game status flag storage area is configured as a storage area represented by 1 byte of data. For example, when the current game status is 2BB, "1" is stored in bit 0 of the storage area.

In the first gaming machine, since the RT state is not provided, the gaming state flag storage area shown in FIG. 19 does not have an area indicating the type of RT state. However, for example, if the RT state is provided, "1" is stored in the bit of the storage area corresponding to the current RT state. In the first gaming machine, data indicating the type of gaming state (mode) in the advantageous zone is stored in a mode flag storage area described later, but it can also be stored and managed in this gaming state flag storage area. The same applies to the gaming zones of the non-advantageous zone and the advantageous zone. It can be managed by providing an advantageous zone flag storage area (not shown), or it can be stored and managed in this gaming state flag storage area. The same applies to gaming states such as the AT state and the ART state. It can be managed by providing an AT state (ART state) flag storage area (not shown), or it can be stored and managed 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 of which is represented by 1 byte of data. For example, if the current mode is start mode, then "1" is stored in bit 0 of storage area 1. Also, if the current mode is heaven A mode, then "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 activated stop button storage area will be described with reference to Fig. 21. The activated stop button storage area is configured as a storage area represented by 1 byte of data. Bits 0 to 2 of the activated 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 not yet been operated (type of reel that is spinning).

For example, if the stop button 8L is the stop button that has been pressed this time, i.e., the activated stop button, then a "1" is stored in bit 0 of the activated stop button storage area. Also, for example, if the stop button 8L is a stop button that has not yet been pressed, i.e., a valid stop button, then a "1" is stored in bit 4. The main CPU 101 distinguishes between the stop button that has been pressed this time and a stop button that has not yet been pressed, based on the data stored in the activated stop button storage area.

(Pressing order storage area)
Next, the configuration of the pressing order storage area will be described with reference to Fig. 22. The pressing order storage area is configured as a storage area represented by 1-byte data. Note that the pressing order indicates the order in which the stop buttons were pressed, i.e., the pressing order (batting order).

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

[6. Processing by the 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 described with reference to Figures 23 to 32. Note that in the description of the various processes shown below, a specific example of the process contents may be described using the specifications of the first gaming machine, but the process contents of the various processes shown below are not limited to this.

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

First, when power is supplied to the pachislot machine 1 (when the power is turned on), the main CPU 101 performs power-on processing (S1). In this processing, various processes required when the power is turned on are performed. The power-on processing will be described in detail later.

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

Then, the main CPU 101 performs a medal acceptance/start check process (S3). In this process, for example, the input state of the medal sensor 31S, the bet switch 6S, the start switch 7S, etc. is checked, and various processes required at the start of the game are performed. Details of the medal acceptance/start check process will be described later.

Then, the main CPU 101 performs a random number value acquisition process (S4). In this process, a random number value for an internal lottery (e.g., a range of 0 to 65535) and a random number value for effects (random number value for other lotteries) used in various lotteries related to gameplay (e.g., a range of 0 to 65535 or a range of 0 to 255) are extracted, and the various extracted random number values are stored in a random number value storage area (not shown) provided in the main RAM 103. Note that the manner in which the various random number values are acquired is not limited to the above. The required number of random number values can be appropriately acquired from each predetermined number range (e.g., a range of 0 to 65535, a range of 0 to 32767, a range of 0 to 255, a range of 0 to 127, etc.).

Then, the main CPU 101 performs an internal lottery process (S5). In this process, various processes are performed that are necessary to determine the internal winning combination based on the internal lottery table and the internal lottery random number value according to the current game state, etc. The internal lottery process will be described in detail later.

Then, the main CPU 101 performs a game start state control process (S6). In this process, when a game is started, if a transition condition for each game state is met (for example, based on a determined internal lottery combination, etc.), various processes are performed to transition the game state according to the transition condition that has been met, or to manage the game period of the current game state. Details of the game start state control process will be described later.

Then, the main CPU 101 performs a start command generation and storage process (S7). In this process, data of the start command to be transmitted 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. 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) described below. The methods of generating, storing, and transmitting data for other commands are also basically the same.

Next, the main CPU 101 performs main side presentation control processing at the start of play (S8). In this processing, when various presentations are to be performed under the control of the main control circuit 100 side (main side) at the start of play, various processes necessary for performing the presentation are performed. For example, if a lock presentation is to be performed at the start of play, the execution of the lock presentation is controlled. Also, if this includes a pseudo game, the progress of the pseudo game (or notification of the pseudo game) is controlled. Also, for example, if the AT state is present and information on a stop operation is to be notified by the instruction monitor, the notification mode is controlled. Also, although details are omitted, if a lock presentation is to be performed, a lock command generation and storage process is performed in this processing.

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

Next, the main CPU 101 performs reel spin start processing (S10). In this processing, it requests that all reels start spinning. Then, when it is requested that all reels start spinning, the drive of each stepping motor 51L, 51C, 51R is controlled by the reel control processing described below (see S203 in FIG. 32), and each reel 3L, 3C, 3R starts spinning. Each reel that has started spinning is accelerated until its rotation speed reaches a constant speed, and then the constant speed is maintained. Also, although details are omitted, in this processing, a reel spin start command generation and storage processing is performed.

Next, the main CPU 101 performs a pull-in priority order storage process (S11). In this process, for each symbol (symbol position) on the spinning reel (all reels in this case), data indicating the pull-in priority order is obtained by referring to the set internal winning combination and the set pull-in priority order table, and stored in a pull-in priority order data storage area (not shown). Although not shown, the symbol code storage process described below is performed prior to this process.

Then, the main CPU 101 performs a reel stop control process (S12). In this process, various processes necessary to stop the rotation of the corresponding reel are performed based on the determined internal winning combination (or information related to various stop control sets set accordingly) and the stop operation state of each stop button 8L, 8C, 8R. The reel stop control process will be described in detail later.

Then, the main CPU 101 performs a winning activation determination process (S13). In this process, it is determined whether the combination of symbols displayed on the active line is one of the combinations of symbols specified in the symbol combination table. For example, it is determined whether there is a bit in which a "1" is stored in the winning activation flag storage area. In addition, although details are omitted, this process also involves the winning activation command generation and storage process.

Then, the main CPU 101 performs a medal payout/replay activation process (S14). In this process, if the symbol combination determined in the above-mentioned winning activation determination process is a symbol combination related to a minor role, the corresponding number of medals is paid out, and if the symbol combination is a symbol combination related to a replay role, various processes necessary to activate a replay in the next game are performed. Note that, for example, if the symbol combination determined in the above-mentioned winning activation determination process is a symbol combination related to a replay role, a process is performed to set a value equal to the number of bets in the current game in the automatic medal counter described below. In addition, in this process, a medal payout signal corresponding to the number of medals to be paid out is output from the external central terminal board 55.

Next, the main CPU 101 performs end-of-game state control processing (S15). In this processing, when the game ends, for various game states, if a transition condition is met (for example, based on the combination of displayed symbols), various processes are performed to transition the game state according to the transition condition that has been met, or to manage the play period of the current game state. Details of the end-of-game state control processing will be described later.

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

In this way, in the pachislot machine 1, one unit game is controlled by performing the above-mentioned processes S2 to S16, and the progress of the game is controlled by repeating these processes. Note that the machine can be configured to perform processes other than these as needed, and can also be configured not to perform some of these processes. In other words, the various processes described above are merely examples.

(Power-on processing)
Next, the power-on process carried out in S1 of the above-mentioned main process will be described with reference to Fig. 24. Fig. 24 is a flow chart showing an example of the procedure of the power-on process.

First, the main CPU 101 performs a power-on initialization process (not shown), then performs a write test on the main RAM 103, and determines whether or not writing to the main RAM 103 was performed normally based on the results of the test (S21). In other words, the main CPU 101 determines whether or not an abnormality has occurred in the main RAM 103.

When the main CPU 101 determines that writing to the main RAM 103 was successful (YES in S21), it determines whether the setting key switch 52 is on (S22). In other words, the main CPU 101 determines whether the setting can be changed.

When the main CPU 101 determines that the setting key switch 52 is in the on state (YES in S22), it performs initialization processing when changing the setting (S23). In this processing, data in a designated storage area in the main RAM 103 is cleared. Note that the designated storage area here is a storage area from which data needs to be erased when changing the setting, such as a carryover role storage area, a game status flag storage area, or a mode flag storage area.

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

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

If the main CPU 101 determines that the setting key switch 52 is not in the OFF state (NO in S26), it waits until the setting key switch 52 is in the OFF state. On the other hand, if it determines that the setting key switch 52 is in the OFF state (YES in S26), it performs an initialization command generation and storage process (S27). In this process, it generates initialization command data to be sent to the sub-control circuit 200 indicating that the setting change process has ended, and stores the generated data in the communication data storage area. After this process, the main CPU 101 ends the power-on process.

When the main CPU 101 determines in S22 that the setting key switch 52 is not in the on state (NO in S22), it determines whether or not the backup data is normal (S28). In other words, the main CPU 101 determines whether or not the various pieces of information backed up when the power supply to the slot machine 1 is cut off (power outage) are normal.

When the main CPU 101 determines that the backup data is normal (YES in S28), it performs a game return process (S29). In this process, it performs a process to return the pachislot machine 1 to the state it was in before the power was cut off. 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), or if it determines in S28 that the backup data is not normal (NO in S28), it performs power-on error processing (S30). Note that errors that occur as a result of this power-on error processing are not resolved by the reset operation described above, but are resolved when a new setting value is set. Therefore, after the power-on error processing, the main CPU 101 does not transition to normal processing (S2 and subsequent steps in FIG. 23) until the power to the pachislot machine 1 is turned off once and a new setting value is set (until the processing of S22 to S26 described above is performed).

(Medal reception and start check processing)
Next, the medal acceptance/start check process performed in S3 of the above-mentioned main process will be described with reference to Fig. 25. Fig. 25 is a flow chart showing an example of the procedure of the medal acceptance/start check process.

First, the main CPU 101 determines whether the value of the automatic insertion medal counter is "0" (S41). In other words, the main CPU 101 determines whether a replay role was won in the previous unit game (whether a replay was activated).

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

When the main CPU 101 determines in S41 that the value of the automatic insertion medal counter is "0" (YES in S41) and after processing in S42, it performs auxiliary medal storage switch check processing (S43). In this processing, it determines whether the auxiliary medal storage switch 33S is in the ON state (i.e., whether a certain number of medals or more are stored in the auxiliary medal storage 33), and if it determines that the auxiliary medal storage switch 33S is in the ON state, it generates an auxiliary medal storage error. In this case, the processing is put on hold until the error is resolved. Furthermore, if it determines that the auxiliary medal storage switch 33S is not in the ON state, this processing is terminated.

Next, the main CPU 101 performs a medal insertion status check process (S44). In this process, the current number of bets and credits are checked, and it is also determined whether the acceptance of medals is prohibited or a selector error has occurred. If medals can be accepted, the state becomes one in which medals can be accepted (a state in which betting operations can be accepted) (acceptance of medals is permitted). Note that if a selector error has occurred, the process is put on hold until the error is resolved.

Then, the main CPU 101 determines whether or not the machine is ready to accept medals (S45). If the main CPU 101 determines that the machine is ready to accept medals (YES in S45), it 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 detection results of the bet switch 6S. Also, although details are omitted, if a bet operation is performed, a medal insertion command generation and storage process is performed in this process. Also, in this process, a medal insertion signal is output from the external centralized terminal board 55.

Then, the main CPU 101 judges whether or not it is possible to insert medals or to give credits (S47). That is, the main CPU 101 judges whether or not the number of bets is "3" and the number of credits is not "50". If the main CPU 101 judges that it is not possible to insert medals or to give credits (that is, the number of bets is "3" and the number of credits is also "50") (NO in S49), it prohibits the acceptance of medals (S48). That is, the main CPU 101 sets the state as one in which it is not possible to accept medals (a state in which betting operations are not acceptable).

If the main CPU 101 determines in S45 that the game is not ready to accept medals (NO in S45), if it determines in S47 that the game is ready to accept medals or receive credits (YES in S47), or after processing S48, it determines whether the number of medals inserted is the number that allows play to begin (S49). Note that in the case of the first gaming machine, this process determines, for example, whether the current number of bets is "2" or "3".

When the main CPU 101 determines that the number of inserted coins is the number required to start playing (YES in S49), it determines whether the start switch 7S is turned on (S50). In other words, the main CPU 101 determines whether the player has performed a start operation.

When the main CPU 101 determines that the start switch 7S is in the ON state (YES in S50), it prohibits the acceptance of medals (S51). After this process, the main CPU 101 then ends the medal acceptance/start check process.

If the main CPU 101 determines in S49 that the number of inserted coins is not enough to start playing (NO in S49), or if it determines in S50 that the start switch 7S is not on (NO in S50), it returns the process to S44.

(Internal lottery processing)
Next, the internal lottery process performed in S5 of the above-mentioned main process will be described with reference to Fig. 26. 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 to check the setting 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 setting value, the number of bets, the game status, etc. (S62). Next, the main CPU 101 acquires a random number value for the internal lottery from the random number value storage area (S63). That is, the main CPU 101 acquires the data of the random number value for the internal lottery acquired in S4 of the main process described above. Note that in this process, if it is determined that the setting 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 and executes the above-mentioned power-on error process (see S30 in FIG. 24).

Next, the main CPU 101 performs an internal winning combination determination process (S64). In this process, the acquired internal lottery random number value is sequentially updated (e.g., updated by addition) using the lottery value of each internal winning combination defined in the set internal lottery table, and it is determined whether the updated result is a predetermined result (e.g., whether it has overflowed). If it is a predetermined result, that internal winning combination is determined as the internal winning combination for this unit game. Note that if the predetermined result is not obtained even after determining all internal winning combinations, the result of this unit game will be a "lose" ("lose" is determined as the internal winning combination).

Then, the main CPU 101 judges whether or not an internal winning combination has been determined (S65). If the main CPU 101 judges that an internal winning combination has not been determined (NO in S65), the process returns to S64. That is, the main CPU 101 sequentially updates the internal winning combinations to be judged (sequentially updates the random number values for the internal lottery) and repeats the process of S64 until judgments have been made for all internal winning combinations (or until an internal winning combination is determined halfway through).

When the main CPU 101 determines that an internal winning role has been determined (YES in S65), it determines whether the determined internal winning role is a role that is not eligible for carryover (i.e., whether it is a minor role or a replay role, rather than a bonus role that is a carryover role) (S66). When the main CPU 101 determines that the determined internal winning role is a role that is not eligible for carryover (YES in S66), it updates the winning flag storage area (S67). In this process, the data in the winning flag storage area is updated based on the internal winning role determined in the process of S64. In other words, the main CPU 101 stores "1" in the bit in the data corresponding to the combination of symbols that are permitted to be displayed in accordance with the determined internal winning role in the winning flag storage area.

If the main CPU 101 determines in S66 that the determined internal winning role is not a role that is not eligible for carryover (NO in S66), and after processing in S67, it determines whether the determined internal winning role is eligible for carryover (i.e., whether it is a bonus role that is a carryover role) (S68).

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

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

When the main CPU 101 determines that the data in the carryover role storage area is not "0" (S71 is NO), it updates the winning flag storage area (S72). In this process, the data stored in the carryover role storage area is reflected in the data in the winning flag storage area. That is, when a bonus role is carried over (or a winning role has been won in the current unit game), the main CPU 101 stores "1" in the bit in the data in the winning flag storage area that corresponds to the combination of symbols that is permitted to be displayed in accordance with the bonus role.

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

(Game start state control process)
Next, the game start state control process performed in S6 of the above-mentioned main process will be described with reference to Fig. 27. Fig. 27 is a flow chart 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, a check is made as to whether or not a transition condition for transitioning from one game state to another game state is satisfied. For example, in the case of transitioning to a flag interval as a predetermined RT state based on winning a predetermined bonus role, this process checks whether or not the predetermined bonus role has been won. In the case of the first gaming machine, the flag interval is not configured as an RT state (i.e., as a game state stored in the game state flag storage area), so this check is not necessary. Also, for example, if there is a specific RT state that starts or ends when a specific transition condition is satisfied and a specific number of games are played, this specific number of games can also be managed in this process.

Then, the main CPU 101 determines whether a transition condition for transitioning to any of the game states has been met (S82). When the main CPU 101 determines that a transition condition for transitioning to any of the game states has been met (YES in S82), it updates the game state flag storage area (S83). That is, the main CPU 101 sets the game state according to the transition condition that has been met. Next, the main CPU 101 performs a setting process according to the set game state (S84). In this process, when it is necessary to set, for example, the game period of the game state or to set a lottery value (lottery table) in various lottery processes other than the internal lottery process in response to the transition of the game state, such setting process is performed as appropriate.

When the main CPU 101 determines in S82 that the transition condition for transitioning to any of the game states has not been met (NO in S82), and after processing S84, it determines whether the current game zone is a non-favorable zone (S85). When the main CPU 101 determines that the current game zone is a non-favorable zone (YES in S85), it performs a favorable zone start condition establishment check process (S86). In this process, when starting play, it checks whether the transition condition for transitioning from a non-favorable zone to a favorable zone (favorable zone start condition) has been met. Note that in the case of the first gaming machine, this process, for example, involves conducting the above-mentioned favorable zone transition lottery, and checking whether the lottery result will start the favorable zone.

Then, the main CPU 101 judges whether the conditions for starting the advantageous zone have been met (S87). If the main CPU 101 judges that the conditions for starting the advantageous zone have not been met (NO in S87), it ends the game start state control process. If the main CPU 101 judges that the conditions for starting the advantageous zone have been met (YES in S87), it performs setting processing at the start of the advantageous zone (S88). That is, the main CPU 101 starts (sets) the advantageous zone. In this process, in response to the start of the advantageous zone, it appropriately performs setting processing such as starting counting various counters (see FIG. 16) related to various limit processes (that is, starting monitoring the game period of a series of advantageous zones).

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

Next, the main CPU 101 performs a setting process according to the set mode (S90). In this process, if it is necessary to set the play period (including the ceiling number of games, etc.) of the set mode or to set the lottery value (lottery table) in various lottery processes other than the internal lottery process, such setting process is appropriately performed. In the case of the first gaming machine, for example, in this process, according to the set destination mode, when the mode is shifted to the pseudo bonus, "55 games" is set as the play period, when the mode is shifted to the end mode, "32 games" is set as the play period, and when the mode is shifted to the other mode, the corresponding ceiling number of games is set. In addition, the lottery value (lottery table) in various lotteries (see Figures 7 and 8, etc.) is set. After this process, the main CPU 101 ends the game start state control process.

When the main CPU 101 determines in S85 that the current play zone is not a non-favorable zone (i.e., it is a favorable zone) (NO in S85), it performs processing at the start of play in the favorable zone (S91). Details of the processing at the start of play in the favorable zone will be described later.

Then, the main CPU 101 performs a check process for determining whether the advantageous zone end condition is met (S92). In this process, when starting play, a check is made to determine whether the transition condition for transitioning from the advantageous zone to the non-advantageous zone (the end condition of the advantageous zone) is met. In the case of the first gaming machine, this process checks, for example, whether the operation conditions for various limit processes have been met based on the number of games in the advantageous zone (see FIG. 16), or whether 32 games have elapsed if the current mode is the end mode.

Next, the main CPU 101 judges whether the end condition of the advantageous zone has been met (S93). When the main CPU 101 judges that the end condition of the advantageous zone has been met (YES in S93), it performs initialization processing at the end of the advantageous zone (S94). That is, the main CPU 101 ends the advantageous zone and sets the non-advantageous zone. In this processing, in response to the end of the advantageous zone, it performs initialization processing to clear all information (that is, information about the advantageous zone) related to, for example, various counters related to various limit processing (see FIG. 16), the mode (game state) during the advantageous zone, and the game period of the mode (including the ceiling game number, etc.). Then, after this processing, the main CPU 101 ends the game start state control processing. Also, when the main CPU 101 judges that the end condition of the advantageous zone has not been met (NO in S93), it ends the game start state control processing.

(Processing at the start of play during advantageous period)
Next, the game start processing during the advantageous period performed in S91 of the game start state control processing described above will be described with reference to Fig. 28. Fig. 28 is a flow chart showing an example of the procedure of the game start processing during the advantageous period.

First, the main CPU 101 performs various counter update processing (at the start of play) (S101). In this processing, for example, various counters related to various limit processing based on the number of games played in the advantageous zone (see FIG. 16), various counters that manage the play period such as various modes (play states) in the advantageous zone, or various counters that manage other advantageous degrees are updated according to predetermined update conditions (for example, subtracting (adding) 1 per game, etc.).

Next, the main CPU 101 judges whether or not it is in a specific mode (AT state) (S102). When the main CPU 101 judges that it is in a specific mode (YES in S102), it performs AT period management processing (at the start of play) (S103). In this processing, for example, when it is possible to extend the play period of the AT state (for example, extending the number of games or adding the number of sets, etc.) at the start of play, it judges whether or not the execution condition of such an extension is established, and performs processing such as extending the play period based on this judgment result (if it is possible to shorten the play period of the AT state, processing related to the shortening is performed). In addition, in this processing, the play period of the AT state may be managed regardless of whether it is extended or not, or the play period of the AT state may be managed in the processing of S101 described above, and only processing related to the extension may be performed in this processing. In the case of the first gaming machine, for example, in this process, the above-mentioned 1G consecutive lottery is performed based on the sub-flag when the advantageous zone is selected, a 1G consecutive lottery is performed, and a process is performed to extend the pseudo bonus according to the lottery result.

Next, the main CPU 101 performs a navigation setting process (S104). In this process, information corresponding to the information of the stop operation notified by the instruction monitor and information corresponding to the information of the stop operation to be included in the start command are set. Note that in this process, it may be possible to determine whether or not to generate navigation. In other words, when a role to be notified is won in the AT state, navigation may not necessarily occur, and in this process, whether or not navigation occurs may be determined according to a predetermined condition (for example, the type of role to be notified or a predetermined probability of navigation occurrence).

When the main CPU 101 determines in S102 that the game is not in a specific mode (NO in S102) and after S104, it determines whether or not the mode transition condition is met (S105). Note that in the case of the first gaming machine, this process determines whether or not the transition mode has been determined according to the result of the mode transition lottery described above, which is based on the sub-flag when the advantageous zone is selected, for example.

When the main CPU 101 determines that the mode transition condition is met (YES in S105), it updates the mode flag storage area (S106). That is, the main CPU 101 sets the mode (game state) in the advantageous zone to which the player has transitioned. In the case of the first gaming machine, for example, this process sets the transition mode determined according to the result of the mode transition lottery described above based on the sub-flag when the advantageous zone is selected.

Then, the main CPU 101 performs a setting process according to the set mode (S107). In this process, if it is necessary to set the play period (including the ceiling number of games, etc.) of the mode according to the set mode, or to set lottery values (lottery tables) in various lottery processes other than the internal lottery process, such setting processes are performed as appropriate. Note that in the case of the first gaming machine, this process is similar to the process of S90 described above, for example. After this process, the main CPU 101 ends the process at the start of play in the advantageous zone. Furthermore, if the main CPU 101 determines that the mode transition condition is not met (NO in S105), it ends the process at the start of play in the advantageous zone.

The state control process at the start of play shown in FIG. 27 and the state control process at the end of play shown in FIG. 30, as well as the process at the start of play during the favorable zone shown in FIG. 28 and the process at the end of play during the favorable zone shown in FIG. 31, are basically almost the same processing configuration. This means that for processes that may be performed either when play starts or when play ends (for example, processes that refer to a determined internal lottery role, such as a game state or mode transition, but the processing result only needs to be reflected by the time the current game ends (or the time the next game starts)), they may be performed in either one of them, and do not mean that similar processes are performed in both cases in duplicate. Therefore, such processes may be performed either when play starts or when play ends.

In contrast, processing that needs to be performed when game play begins (such as the navigation setting processing described above) may be performed when game play begins, and processing that needs to be performed when game play ends (such as processing that references the combination of displayed symbols) may be performed when game play ends. Also, for example, processing that needs to be performed at a specified time after game play begins and before game play ends, or processing where it is better to perform processing (such as processing that references the stop operation mode of the first stop operation) may be performed at that time.

(Reel stop control process)
Next, the reel stop control process performed in S12 of the above-mentioned main process will be described with reference to Fig. 29. 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 rotation speed of all reels has reached a predetermined constant speed (e.g., 80 rotations per minute) (i.e., whether they are rotating at a constant speed) (S111). If the main CPU 101 determines that all reels are not rotating at a constant speed (NO in S111), it waits until all reels rotate at the constant speed before processing. On the other hand, if it determines that all reels are rotating at a constant speed (YES in S111), it allows each reel to stop (S112). In other words, the main CPU 101 enables each stop button. In addition, the activated 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 activated stop button storage area).

Then, the main CPU 101 determines whether or not 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 process waits until a valid stop button is operated. When automatic stop control is to be performed, this wait time is measured, and the automatic stop control can be performed when the measurement result reaches a predetermined time.

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

Then, the main CPU 101 determines the reel to be controlled based on the activated stop button (S115). In this process, for example, if stop button 8L is pressed, reel 3L is determined to be the reel to be controlled.

Then, 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 (e.g., "0" to "19"). In this process, for example, when the stop button 8L is pressed, the symbol position data of the middle area of the reel 3L at the time the stop button 8L was pressed is stored as the stop start position.

Then, the main CPU 101 performs a process for determining the number of sliding pieces (S117). In this process, for example, the main CPU 101 refers to the number of sliding pieces specified in the above-mentioned stop table and the data in the above-mentioned pull-in priority data storage area, and determines the most appropriate number of sliding pieces (amount of movement of the symbols).

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

Then, the main CPU 101 performs a reel stop command generation and storage process (S119). In this process, data for the 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 be configured to include parameters that can specify not only the intended stop position, but also the stop start position and the number of sliding pieces.

Next, the main CPU 101 performs a pattern code storage process (S120). In this process, the main CPU 101 updates the pattern code storage area while also referring to the type of pattern (pattern code) at the intended stopping position of the reel for which the intended stopping position has already been determined. Next, the main CPU 101 determines whether or not there is an active stop button (S121). In other words, the main CPU 101 determines whether or not there is a reel that is still spinning (whether or not a stopping operation has been performed on all reels).

When the main CPU 101 determines that a valid stop button is present (YES in S121), it performs a control change process (S122). In this process, if it is necessary to change the stop table or the pull priority table set in the above-mentioned reel stop initial setting process, for example, depending on the stop operation mode performed by the player up to this point, the various information required for such stop control is reset.

Then, the main CPU 101 performs a pull-in priority order storage process (S123). In this process, for each symbol (symbol position) on the spinning reel, the main CPU 101 acquires data indicating the pull-in priority order by referring to the set internal winning combination and the set pull-in priority order table while also referring to the type of symbol at the intended stop position on the reel whose intended stop position has already been determined, and stores the data in the pull-in priority order data storage area. After this process, the main CPU 101 returns the process to S113. Furthermore, if the main CPU 101 determines that there is no valid stop button (NO in S121), it ends the reel stop control process.

(Game End State Control Processing)
Next, the game end state control process carried out in S15 of the above-mentioned main process will be described with reference to Fig. 30. Fig. 30 is a flow chart showing an example of the procedure of the game end state control process.

First, the main CPU 101 performs a game state transition condition satisfaction check process (S131). In this process, when the game ends, a check is made as to whether a transition condition for transitioning from one game state to another game state has been satisfied. For example, when a transition to a predetermined RT state or a predetermined bonus state is made based on the display of a predetermined symbol combination, this process checks whether the predetermined symbol combination has been displayed. Also, when in a predetermined RT state or a predetermined bonus state, this process checks whether the termination conditions for these game states have been satisfied. Note that in the case of the first gaming machine, this process checks whether, for example, a symbol combination related to 2BB or 3BB has been displayed. Also, when in a 2BB state or a 3BB state, for example, a check is made as to whether the termination conditions for these game states have been satisfied by the payout of medals.

Next, the main CPU 101 determines whether a transition condition for transitioning to any of the game states has been met (S132). When the main CPU 101 determines that a transition condition for transitioning to any of the game states has been met (YES in S132), it updates the game state flag storage area (S133). That is, the main CPU 101 sets the game state according to the transition condition that has been met. Note that 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 game state flag storage area, and the 2BB state or 3BB state is set. Also, for example, when the game state is in the 2BB state or 3BB state, if the end condition for these game states is met, bit 0 or bit 1 of the game state flag storage area is updated to "0".

Then, the main CPU 101 performs a setting process according to the set gaming state (S134). In this process, when it is necessary to set the gaming period of the gaming state or to set lottery values (lottery tables) in various lottery processes other than the internal lottery process in response to the transition of the gaming state, such setting processes are appropriately performed. Note that in the case of the first gaming machine, for example, if the 2BB state is set, the payout number as the termination condition is set to "1", and if the 3BB state is set, the payout number as the termination condition is set to "176".

When the main CPU 101 determines in S132 that the transition condition for transitioning to any of the game states has not been met (NO in S132), and after processing S134, it determines whether the current game zone is a non-favorable zone (S135). When the main CPU 101 determines that the current game zone is a non-favorable zone (YES in S135), it performs a favorable zone start condition establishment check process (S136). As described above, in a non-favorable zone, only processing that references the determined internal lottery role is possible, so this process is the same as the process of S86 described above (game start state control process).

Then, the main CPU 101 determines whether the conditions for starting the advantageous zone have been met (S137). If the main CPU 101 determines that the conditions for starting the advantageous zone have not been met (NO in S137), it ends the state control process at the end of the game. Also, if the main CPU 101 determines that the conditions for starting the advantageous zone have been met (YES in S137), it performs setting processing at the start of the advantageous zone (S138). As described above, in the non-advantageous zone, only processing that references the determined internal lottery role is possible, so this processing is the same as the processing of S88 described above (state control process at the start of the game).

Then, the main CPU 101 updates the mode flag storage area (S139). That is, the main CPU 101 sets the mode (game state) during the advantageous period that has started. As described above, in the non-advantageous period, only processing that references the determined internal lottery role is possible, so this processing is the same as the processing of S89 described above (game start state control processing).

Next, the main CPU 101 performs a setting process according to the set mode (S140). In this process, if it is necessary to set the play period (including the ceiling number of games, etc.) for the set mode or to set lottery values (lottery tables) for various lottery processes other than the internal lottery process, such setting processes are performed as appropriate. As described above, in the non-advantageous zone, only processing that references the determined internal lottery role is possible, so this process is the same as the process of S90 described above (state control process at the start of play).

When the main CPU 101 determines in S135 that the current play period is not a non-favorable period (i.e., it is a favorable period) (NO in S135), it performs processing at the end of play during the favorable period (S141). Details of the processing at the end of play during the favorable period will be described later.

Then, the main CPU 101 performs a check process for determining whether the advantageous zone end condition has been met (S142). In this process, when the game ends, a check is made as to whether the transition condition for transitioning from the advantageous zone to the non-advantageous zone (the end condition of the advantageous zone) has been met. Note that in the case of the first gaming machine, this process checks, for example, whether the operating conditions for various limit processes have been met based on the payout number during the advantageous zone (see FIG. 16), or whether 32 games have elapsed if the current mode is the end mode.

Next, the main CPU 101 judges whether the end condition of the advantageous zone has been met (S143). When the main CPU 101 judges that the end condition of the advantageous zone has been met (YES in S143), it performs initialization processing at the end of the advantageous zone (S144). That is, the main CPU 101 ends the advantageous zone and sets the non-advantageous zone. In this processing, in response to the end of the advantageous zone, for example, it performs initialization processing to clear all information (i.e., information about the advantageous zone) related to various counters (see FIG. 16) related to various limit processing, the mode (game state) during the advantageous zone, and the game period of the mode (including the ceiling game number, etc.). Then, after this processing, the main CPU 101 ends the game end state control processing. Also, when the main CPU 101 judges that the end condition of the advantageous zone has not been met (NO in S143), it ends the game end state control processing.

(Processing at the end of play during advantageous period)
Next, the game end processing during the advantageous period performed in S141 of the game end state control processing described above will be described with reference to Fig. 31. Fig. 31 is a flow chart showing an example of the procedure of the game end processing during the advantageous period.

First, the main CPU 101 performs various counter update processing (at the end of play) (S151). In this processing, for example, various counters related to various limit processing based on the payout number during the favorable zone (see FIG. 16), various counters that manage the play period such as various modes (play states) during the favorable zone, or various counters that manage the degree of advantage are updated according to predetermined update conditions (for example, the payout number, the number of times a predetermined combination of symbols is displayed, the stop operation mode, etc.).

Next, the main CPU 101 judges whether or not the specific mode (AT state) is in progress (S152). When the main CPU 101 judges that the specific mode is in progress (YES in S152), it performs AT period management processing (at the end of play) (S153). In this processing, for example, when the play ends and the play period of the AT state can be extended (for example, by extending the number of games or adding the number of sets), it judges whether or not the conditions for such an extension are met, and performs processing such as extending the play period based on the judgment result (if the play period of the AT state can be shortened, processing related to the shortening is performed). In addition, in this processing, the play period of the AT state may be managed regardless of whether it is extended or not, or the play period of the AT state may be managed in the processing of S151 described above, and only processing related to the extension may be performed in this processing. In addition, in the case of the first gaming machine, in this processing, for example, the above-mentioned 1G consecutive lottery is performed based on the sub-flag when the advantageous zone is entered, and processing for extending the pseudo bonus is performed according to the lottery result.

When the main CPU 101 determines that the specific mode is not in progress (NO in S152) and after S153, it determines whether the mode transition condition is met (S154). In the case of the first gaming machine, this process determines whether the transition mode has been determined according to the result of the mode transition lottery described above based on the sub-flag when the advantageous zone is entered.

When the main CPU 101 determines that the mode transition condition is met (YES in S154), it updates the mode flag storage area (S155). That is, the main CPU 101 sets the mode (game state) in the advantageous zone to which the player has transitioned. In the case of the first gaming machine, for example, this process sets the transition mode determined according to the result of the mode transition lottery described above based on the sub-flag when the advantageous zone is entered.

Then, the main CPU 101 performs a setting process according to the set mode (S156). In this process, if it is necessary to set the play period (including the ceiling number of games, etc.) of the mode according to the set mode, or to set the lottery value (lottery table) in various lottery processes other than the internal lottery process, such setting process is performed as appropriate. Note that in the case of the first gaming machine, this process is similar to the process of S140 described above, for example. Then, after this process, the main CPU 101 ends the process at the end of play during the advantageous period. Furthermore, if the main CPU 101 determines that the mode transition condition is not satisfied (NO in S154), it ends the process at the end of play during the advantageous period.

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

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

First, the main CPU 101 performs a register save process (S201). Next, the main CPU 101 performs an input port check process (S202). In this process, the input states (on or off) 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 is compared with the input state at the time of the current interrupt to check whether there has been a change in the input state. If there has been a change in the input state, the change is stored in input port storage area 0 (not shown) of the main RAM 103, and input states that have not changed are stored as they are in input port storage area 1 (not shown) of the main RAM 103.

Then, the main CPU 101 performs a reel control process (S203). In this process, it controls the drive of each stepping motor 51L, 51C, 51R, and controls the rotation and stopping of each reel 3L, 3C, 3R. Next, the main CPU 101 performs a communication data transmission process (S204). In this process, it transmits each parameter of each command stored in the communication data storage area to the sub-control circuit 200. Note that 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 are transmitted to the sub-control circuit 200 as an input state command.

In this embodiment, the various command data is temporarily stored in the communication data storage area and then transmitted to the sub-control circuit 200 in periodic interrupt processing; however, for example, the various command data may be directly stored in a communication circuit (not shown) provided in the main control circuit 100 and transmitted to the sub-control circuit 200 without being stored in the communication data storage area. Also, although detailed explanation is omitted in this embodiment, the various command data is transmitted to the sub-control circuit 200 by serial communication; however, for example, the various command data may be transmitted to the sub-control circuit 200 by parallel communication.

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

Then, the main CPU 101 performs an error detection process (S207). In this process, it detects 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 open/close 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. If various error states have occurred and if the input state of the door open/close monitoring switch 56 is open (off), a security signal is output from the external central terminal board 55.

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

[7. Processing by the Sub-Control Circuit]
Next, 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 with reference to Fig. 33. Fig. 33 is a flow chart showing an example of the overview of the sub-side control processing.

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 modifications, but not so many restrictions are placed on the sub-control circuit 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 use various configurations depending on the type and number of connected presentation devices, the type of presentation performed by the presentation devices, etc., and the manufacturing costs, etc. This is why it is written "Overview" in Figure 33.

First, when the power is turned on, the sub-CPU 201 performs power-on processing (S301 and S302) in the same manner as the main CPU 101. During this processing, processing is performed such as detecting whether or not an abnormality has occurred when the power is turned on, initializing data stored in the sub-RAM 203, and starting various tasks required for performing various performance execution control processing described below.

When the sub-CPU 201 receives a command sent from the main control circuit 100, it performs a performance execution control process when the command is received (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 the settings have been changed, the appropriate initialization process is performed on the sub side, and if the settings have not been changed, the process of restoring the sub side to the state before the power outage is performed.

For example, when a start command is received, the parameter information of the received start command is referenced, and if the state is not AT, the content of the presentation that suggests or notifies the internal winning combination or game state, etc. is determined (by lottery if necessary), and various presentation devices are controlled so that the presentation of the determined content is executed. Furthermore, if the state is AT, in addition to this, the content of the presentation that notifies the advantageous stop operation mode is determined, and various presentation devices are controlled so that the presentation of the determined content is executed.

For example, when a lock command is received, the parameter information of the received lock command is referenced, the content of the effect linked to the content of the lock effect is determined, and various effect devices are controlled so that the effect of the determined content is executed.For example, when a reel stop command is received, the parameter information of the received reel stop command is referenced, the content of the effect linked to the stop start position or the planned stop position (or simply the number of stop operations performed, etc.) is determined, and various effect devices are controlled so that the effect of the determined content is executed.For example, when a winning activation command is received, the parameter information of the received winning activation command is referenced, and if a bonus is awarded, the content of the effect linked to the bonus to be awarded is determined, and various effect devices are controlled so that the effect of the determined content is executed.

The sub-CPU 201 also performs processing for controlling the execution of effects when effect buttons 10a, 10b connected to the sub-control board 72 (including those connected via the sub-relay board 74) are operated (S305 and S306). In this processing, for example, when an effect button in accordance with an effect is operated while an operation-linked effect is being executed, the sub-CPU 201 controls various effect devices so that the content of the operation-linked effect changes. Also, for example, when an effect button is operated to call up a user menu (described below) while not playing, the sub-CPU 201 performs control to display the user menu. Also, when an effect button is operated to perform a selection or decision operation while the user menu is being displayed, the sub-CPU 201 performs control in accordance with these operations.

In addition, when a trigger other than the above-mentioned trigger occurs, the sub-CPU 201 performs other effect execution control processing (S307). In this processing, for example, when a non-operation period during which no operation related to the game or user menu is performed reaches a predetermined period (e.g., about 30 seconds), the sub-CPU 201 determines the content of the effect related to the demo state notification and controls various effect devices so that the effect of the determined content is executed.

[8. Other functions of Pachislot machines]
As described above, the pachislot machine 1 has various functions for controlling the game and the presentation, as well as various configurations for implementing these functions, but it can also have other functions, such as those shown below. In the following, an example of other functions on the player's side and an example of other functions on the gaming facility's side will be described.

[8-1. Player side]
For example, a user menu is displayed by the player's presentation operation, a desired menu is selected from the user menu, and then the player performs an appropriate selection and decision operation for the selected menu, enabling the player to obtain various information and make various settings.

For example, when the "arrangement and payout table" is selected and confirmed, an information screen is displayed on the performance display section, which allows the player to check the pattern arrangement on the pachislot machine 1, the specified pattern combination, and the payout (contents of the bonus) when the combination is won.

For example, when "Volume/Light Adjustment" is selected and confirmed, a setting screen is displayed on the performance display unit, which allows the brightness of the various display devices in the slot machine 1, the volume of the sound output from the speakers, or the light intensity of the lamps and LEDs to be set. During such settings, in order to allow for more detailed settings or to make it easier to accept settings-related operations, the various operation units that accept the player's game operations can be used as part of the operation unit that accepts settings-related operations (i.e., the operation unit that accepts performance operations).

For example, when "Custom" is selected and confirmed, a setting screen is displayed on the performance display unit that allows the setting of the performance mode in the pachislot machine 1 (for example, the type of character used in the performance (including the type of the character (display mode) itself, the type of voice corresponding to the character, or the type of costume or item (individual display mode) related to the character, etc.), the probability of the performance occurring (including the type of expectation when the performance occurs, etc.), or the mode of suggestion or notification (including the timing of performance execution, etc.)). Note that when setting in this manner, in order to allow for more detailed settings or to make it easier to accept operations related to the settings, the various operation units that accept the player's game operations can be used as part of the operation unit that accepts operations related to the settings (i.e., the operation unit that accepts performance operations).

For example, when "UniMemo" is selected and confirmed, it becomes possible to receive an information provision service using the player's mobile terminal (e.g., a mobile phone, smartphone, etc.). With such an information provision service, for example, the player can log in to start playing (play can also be started without logging in), and by logging out when the game is over, the player can confirm or obtain game history information (e.g., information according to various game results, such as the total number of games played, the number of times an advantageous game state occurred, and the maximum number of coins won).

In addition, for example, the game history information also includes information regarding associated benefits, such as information indicating the type of character that can be displayed during play and the type of music that can be output depending on the game result (achievement of the unlocking conditions), and information indicating the type of character that can be displayed on the player's mobile terminal and the type of music that can be output.

Note that various methods can be used for logging in and out of such information provision services. For example, the player may use his/her terminal to read a two-dimensional code displayed on the display screen to log in and out, or the player may enter a password or memorize a password (specifically, for example, when logging out at the end of a game, instead of the two-dimensional code, a four- to ten-digit character string may be displayed as a password to be entered next time, which the player may obtain by writing it down on paper or taking a photo of it on a mobile device, and the password obtained in this way may be entered when logging in before the start of the next game). These methods can also be combined as appropriate to log in and out.

[8-2. Amusement store side]
For example, a hall menu is displayed by a setting confirmation operation (which may be a setting change operation or other operation by the amusement facility's administrator) by the amusement facility's administrator, a desired menu is selected from the hall menu, and then an appropriate selection/determination operation is performed for the selected menu, allowing the amusement facility's administrator to obtain various information and make various settings.

For example, when "Time Setting" is selected and confirmed, a setting screen that allows the date and time, etc. of the slot machine 1 to be set is displayed in the performance display section. The date and time can also be configured to be automatically updated, for example, during the sub-side power-on process described above (see S302 in FIG. 33).

For example, when "Total Medal Information" is selected and confirmed, an information screen is displayed on the performance display section, which allows the user to check historical information showing the number of coins inserted and paid out during a specified period (for example, each business day for seven business days) on the pachislot machine 1. Note that such a menu can also be configured as a menu in the user menu.

For example, when "setting change/confirmation history" is selected and confirmed, an information screen is displayed on the display section, which allows the user to check history information showing the number of setting change operations and setting confirmation operations within a specified period (for example, each business day of seven business days) on the slot machine 1. For example, when "error information history" is selected and confirmed, an information screen is displayed on the display section, which allows the user to check history information showing the date and time of error occurrences and their contents within a specified period (for example, each business day of seven business days) on the slot machine 1.

For example, when "Monitoring History" is selected and confirmed, an information screen is displayed on the display section, which allows the user to check historical information showing the date and time of door opening within a specified period (for example, each business day for seven business days) on the Pachislot machine 1, as well as that period. For example, when "Warning Settings" is selected and confirmed, a setting screen is displayed on the display section, which allows the user to set the manner and frequency of various warning notifications on the Pachislot machine 1.

For example, when "power saving mode setting" is selected and confirmed, a setting screen is displayed on the effect display section, which allows the user to set whether or not to activate the power saving function of the pachislot machine 1. Such a menu can also be configured as a menu in a user menu. Furthermore, when making such settings, in order to allow for more detailed settings or to make it easier to accept operations related to the settings, the various operation sections that accept the player's game operations can be used as part of the operation section that accepts operations related to the settings (i.e., the operation section that accepts effect operations).

For example, when the "limit setting" is selected and confirmed, a setting screen is displayed on the display section, which allows the user to set whether or not to activate the limit function in the slot machine 1. The limit function is a function that, when a predetermined operating condition is met, renders the machine unplayable until the manager of the gaming establishment cancels the condition (for example, a reset operation). The predetermined operating condition may be met, for example, when the advantageous zone is forcibly ended by the execution of the limit process described above, or when a specific state (for example, a bonus state, an increase zone, or an advantageous zone (including an operating zone)) ends. When the limit function is set to ON, the automatic settlement function described below may also be set to ON in conjunction with this.

For example, when "automatic settlement setting" is selected and confirmed, a setting screen is displayed on the effect display section, which allows the user to set whether or not to activate the automatic settlement function of the pachislot machine 1. The automatic settlement function is a function in which credits are automatically settled (i.e., all credited gaming value is automatically returned) when a predetermined operating condition is met. The predetermined operating condition may be met, for example, when the advantageous zone is forcibly ended by the execution of the limit process described above, or when a specific state (for example, either the bonus state, the increase zone, or the advantageous zone (including the effect zone)) ends. When the automatic settlement function is set to ON, the above-mentioned limit function may also be set to ON in conjunction with this.

When setting the limit function or automatic settlement function, in order to allow for more detailed settings or to make it easier to accept settings-related operations, various operation units that accept the player's game operations can be used as part of the operation unit that accepts operations related to the settings (i.e., the operation unit that accepts presentation operations). However, in this case, since it is not desirable to unnecessarily increase the number of operation units that can accept operations, it is also possible to use only a specific operation unit (e.g., a stop button) as part of the operation unit that accepts operations related to the settings.

[9. Extension Example]
Up to this point, the pachislot 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 machines to which the invention according to this embodiment can be applied are not limited to this. For example, the invention according to this embodiment can be applied to gaming machines called "pachinko machines" and "slot machines", and similar effects can be obtained. That is, the invention according to this embodiment can be applied to all gaming machines that can play games (perform gaming control) according to the game actions (operations) of the player. In addition, the configurations and functions of gaming machines including the pachislot machine 1 are not limited to those described above, and various changes and extensions are possible. Below, such an extension example will be described, although it is merely an example.

(Pachinko machine)
A pachinko machine has, for example, a game board with a game area in which game balls can roll and flow down, a glass door including protective glass that protects the game area while making it visible from the outside, a performance display device provided in a specified area of the game area (which may be provided outside the game area), a payout unit that pays out game balls, and a board unit including various control boards that perform various controls related to the game and performance, and these are supported by a frame body (which may be simply referred to as a "frame" or the like).

In addition, the front side of the pachinko machine is provided with, for example, a launch handle as one of the operation means for the player, an upper tray in which game balls to be used in the game can be stored, and a lower tray in which paid-out game balls can be stored. Many pachinko machines are also provided with the above-mentioned performance buttons and movable performance devices. In addition, the game area is provided with, for example, a starting area (sometimes called a "starting hole") or a specific area (sometimes called a "V winning hole") through which the game ball can pass, a variable winning device (sometimes called a "big winning hole") that can shift between a state in which it is easy for the game ball to win and a state in which it is difficult for the game ball to win, and a variable display device that can variably display identification information (sometimes called a "design" or the like, including "special designs" and "normal designs").

In a pachinko machine, a player operates a launch handle to launch a game ball into a game area to play. For example, when a launched game ball passes through a starting area, a variable display is started. At this time, whether or not to transition the game state (for example, whether or not to transition to a big win game state or a small win game state that is advantageous to the player) is determined based on a probability according to the current state (for example, whether or not the game state is in a certain probability game state with a relatively high probability of winning) and the type of starting area (that is, whether or not to transition the game state is determined by lottery (or judgment)). After that, when a stop condition for the variable display (for example, the set variable time has ended) is established, the variable display stops in a stop mode according to the above-mentioned determination result. At this time, if the above-mentioned determination result is one that transitions the game state (a win), the stop mode that is stopped also becomes a display result corresponding to the win, and the game state corresponding to the win is transitioned in response to the display result being displayed. On the other hand, if the above decision result is one that does not change the game state (miss), the display result for the stop mode also corresponds to a miss, and the game state does not change. For example, when the launched game ball passes through a specific area (specific areas are usually placed in a state where it is difficult for the game ball to pass through), it is decided to change the game state regardless of the variable display device.

In other words, in a pachislot machine 1, the game begins when the player bets the necessary medals and performs a start operation, whereas in a pachinko machine, the player fires the necessary game balls by operating a launch handle, and the game begins when the game ball passes through a starting area, for example. However, both machines have in common the fact that the game begins with the player's gaming action. Pachislot machine 1 and pachinko machines also have in common that the stop mode that is ultimately permitted to be displayed (in other words, the content of the bonus to be awarded) is determined when the start trigger is met.

Furthermore, the Pachislot machine 1 basically stops the variable display by the player's stop operation, whereas the Pachinko machine stops the variable display when the stop condition is met (without the player's stop operation), which is different, but they are similar in that they both stop the variable display according to a pre-determined result and award a bonus according to the stopped state. The Pachislot machine 1 and the Pachinko machine are also similar in that they are capable of executing effects related to the game. For example, the effect display device functions as the above-mentioned effect display section or information display section. Furthermore, it goes without saying that the Pachinko machine may also be provided with effect execution means such as the above-mentioned lamps, speakers, or other effect devices, and effects may be executed by these.

In many pachinko machines, the decorative symbols (which are sometimes also referred to as "identification information") are displayed in a variable manner on the performance display device. As mentioned above, the actual game results are displayed on the variable display device, but since the variable display device is small and the display results are shown as lighting patterns of multiple LEDs, it is often difficult for the player to recognize the game results. For this reason, the mainstream pachinko machines are designed to play by varying (and stopping) decorative symbols on the performance display device in conjunction with the variable display of the variable display device. And, the variable display of such decorative symbols (for presentation purposes, the variable display may start after a certain delay when the start trigger is established, or may temporarily stop before the stop condition is established) is basically the same as the variable table device described above, and displays the identification information variably or statically as the game progresses (for example, in the case of a win, the decorative symbols are displayed statically in a special stop mode (for example, matching symbols), while in the case of a loss, the decorative symbols are displayed statically in a non-special stop mode (for example, scattered symbols)). Therefore, it is possible to apply the invention according to this embodiment to this as one aspect of the variable display unit described above.

In other words, in this embodiment, the various items described as the configuration of the external structure or internal structure of the pachislot machine 1 can be applied to the configuration of the external structure or internal structure of a pachinko machine, except for those that have properties unique to the pachislot machine 1 (for example, those that require medals and cannot be replaced by game balls, etc.).

In pachinko machines, various controls related to the game are performed by a main control circuit acting as a game control unit implemented on a main control board (including some payout-related controls that may be performed by a payout control circuit implemented on a payout control board electrically connected to the main control board), and various controls related to the presentation are performed by a sub-control circuit acting as a presentation control unit implemented on a sub-control board. Therefore, the various items described as the electrical configuration of pachinko machine 1 can be applied to the electrical configuration of pachinko machines, except for those that have characteristics unique to pachinko machine 1 (for example, those related to the stop operation, etc.).

As described above, the pachislot machine 1 can provide game states that are relatively advantageous to the player (or may be disadvantageous depending on the configuration), such as a bonus state, an RT state, an AT state, and an ART state that combines these. For example, in the bonus state, the lottery mode for the small role is made more advantageous than the non-bonus state, making it possible to continue a state in which medals are more likely to be awarded (increased) for a certain period of time; in the RT state, the lottery mode for the replay role is made more advantageous than the non-RT state, making it possible to continue a state in which losses are less likely to occur (and, as a result, medals are less likely to decrease) for a certain period of time; and in the AT state, a favorable stop operation mode is notified, making it possible to continue a state in which medals are more likely to be awarded (increased) for a certain period of time.

In contrast, pachinko machines can also provide various game states with similar characteristics. For example, in a big win game state or a small win game state, the variable winning device is controlled differently from the normal state, making it possible to transition to a state in which game balls are more likely to win, and thus making it possible to continue a state in which game balls are more likely to be awarded (increased) for a certain period of time. Also, for example, in a time-saving game state (sometimes called an "electric support state"), normal symbols are controlled differently from the normal state, making it possible to create a state in which game balls are more likely to pass through the starting area, thereby increasing the frequency of lottery draws by the variable display device and making it possible to continue a state in which game balls are less likely to decrease for a certain period of time. Also, for example, in a sure-win game state, special symbols are controlled differently from the normal state, making it possible to continue a state in which the variable display device has a higher probability of winning (as a result, game balls are more likely to increase) for a certain period of time.

In other words, in this embodiment, the various matters described as the configuration of control related to the transition (or shift) of the game state as the playability of the Pachislot machine 1 can be applied as the configuration of control related to the transition (or shift) of the game state of a Pachinko machine, except for those that have properties unique to the Pachislot machine 1 (for example, those that involve transitions between play zones, etc.). The same applies to the various other matters described as the playability of the Pachislot machine 1.

In addition, in pachinko machines, it is possible to switch to the time-saving game state when the number of plays in the non-time-saving game state (normal game state) reaches a specified number. In other words, pachinko machines can also be equipped with a ceiling function (a function that can switch to a favorable state (e.g., time-saving game state) as a relief from being stuck if an unfavorable state (e.g., normal game state) continues for a predetermined period (e.g., 900 games (spins)) without switching to a favorable state (e.g., jackpot game state)). Therefore, the various matters described as the configuration related to the ceiling function of pachinko slot machine 1 can be applied as the configuration related to the ceiling function of pachinko machines.

In addition, in a pachinko machine, when the stop state of the variable display device during a non-time-saving game state (normal game state) corresponds to a specific miss, this can trigger a transition to a time-saving game state. In other words, a transition (not triggered by a transition to a jackpot game state, etc.) is possible in a pachinko machine as well, due to the display of a specific display result (specific combination of symbols). Therefore, for example, the various matters described as configurations related to a transition (transition) to an RT state due to the display of a specific combination of symbols in a pachinko slot machine 1 can be applied as configurations related to a transition (transition) to a time-saving game state due to the display of a specific display result in a pachinko machine.

(Medalless gaming machine)
In the pachislot machine 1 of this embodiment, play begins with the player performing a betting operation (i.e., inserting held medals into the medal insertion slot 5 to place a bet, or operating the MAX BET button 6a or 1 BET button 6b to bet credited medals) as one of the starting conditions, and if medals are to be paid out when the game ends, the hopper device 32 is driven to pay out medals from the medal payout outlet 11, or the medals are credited, as described above, but the configuration of the pachislot machine 1 is not limited to this.

For example, the invention according to this embodiment can be applied to all forms in which a player bets the gaming value required for a game, plays the game based on that bet, and a bonus is awarded (e.g., gaming value is awarded) based on the results of the game. In other words, the invention can be applied not only to forms in which medals are physically inserted (bet) and medals are paid out by the player's actions, but also to those in which the gaming value held by the player is electromagnetically managed inside the pachislot machine 1 (or, even if not electromagnetically, at least managed in a manner in which the player cannot directly touch the gaming value), allowing for medal-free play. Here, such a pachislot machine 1 is referred to as a "medalless gaming machine." Note that medal-less gaming machines are sometimes referred to as "managed gaming machines" or "enclosed gaming machines," etc.

The game value held by the player may be electromagnetically managed by the main control circuit 100 (main control board 71) itself, or by a game value management device (hereinafter, such a management device may be described as a "medal count control board") that is attached (connected) to the main control circuit 100 (main control board 71). An example of the installation of this game value management device is described below.

The game value management device is a device equipped with at least a ROM and a RWM (or a RAM) and installed in the slot machine 1, and is connected to an external game value providing device (hereinafter, such a game value providing device may be described as a "communication-only unit") for two-way communication via a communication device (hereinafter, such a communication device may be described as a "connection terminal board"). The game value management device performs necessary communication with the external game value providing device, and can perform a game value lending operation (i.e., an operation of providing game value required for a player to perform a betting operation of game value), a game value granting operation (i.e., an operation of providing the game value related to the grant to the player when a winning combination related to the grant of game value (the combination is established) is won), and an operation of electromagnetically recording the game value provided by these operations. The game value providing device is sometimes called a "game value (game medium) handling device," "game value (game medium) lending device," or "sand."

The external gaming value providing device is also connected to an external ball dispensing management device (ball dispensing management server), and the gaming value management device is configured to be able to transmit ball dispensing management information to the external ball dispensing management device via a communication device and the external gaming value providing device. Here, the ball dispensing management information is composed of various pieces of information necessary to enable the external ball dispensing management device to manage dispensing balls. An example of ball dispensing management information will be described later. The external gaming value providing device and the external ball dispensing management device are connected, for example, by an internet line.

Here, "balls paid out" directly means the number of gaming media paid out, but in this embodiment, the concept also includes the degree of benefit given to the player, such as the difference (net increase) between the number of paid out and the number of bets (for example, how much the player gained (how much the gaming establishment lost)), or how much the player lost (how much the gaming establishment gained), the duration of an advantageous state (for example, a bonus state, an AT state, or a series of advantageous periods, etc.), or the degree of gambling assumed by a combination of these, etc.

For example, a retained game value number display device (not shown) that displays the number of retained game values may be provided on the front side of the pachislot machine 1, and the game value management device may manage the number of game values displayed on this retained game value number display device based on the management results of the number of game values. In other words, the game value management device may not only record the total number of game values that a player can use for playing by electromagnetic means, but may also be configured to be able to control the display of the recorded results. In this case, it is preferable that the game value management device has the ability to allow a player to freely transmit a signal indicating the number of recorded game values to an external game value providing device, and also has the ability to prevent the number of recorded game values from being reduced except when the player directly operates it, and also has the ability to transmit the signal indicating the number of recorded game values only via a communication device.

The gaming value management device may have not only a function of electromagnetically managing the gaming value of the player using an external gaming value providing device, but also a function of managing the number of gaming values bet by the physical action of the player and the number of gaming values paid out by the physical action of the pachinko slot machine 1. In other words, it may be capable of managing the actual insertion and payout of medals in a conventional pachinko slot machine 1. In this way, the pachinko slot machine 1 can be controlled by a conventional method, or by a method such as the medal-less gaming machine described above, so that the pachinko slot machine 1 can have a common configuration regardless of the specification. In this case, the gaming value management device can adopt a method of directly controlling the selector 31 and hopper device 32 described above, or a method of indirectly controlling them by controlling them by the main control circuit 100 (main control board 71) and transmitting the control results.

In addition to the above, the pachislot machine 1 may be provided with various operation means necessary for the operation of the medal-less gaming machine, such as a lending operation means and a return (settlement) operation means that can be operated by the player. The gaming value providing device may be provided with various operation means necessary for the operation of the medal-less gaming machine, such as a lending operation means and a return operation means that can be operated by the player, in addition to various devices such as an insertion slot for valuables such as paper money, an insertion slot for recording media (e.g., IC cards), and a non-contact communication antenna for depositing electronic money from a mobile terminal (all not shown). Note that insertable recording media include not only non-member recording media issued on the day at a gaming establishment, but also member recording media held by members of the gaming establishment. The gaming value recorded on a non-member recording medium is valid only on the day (it becomes invalid from the next day onwards), but the gaming value recorded on a member recording medium is valid from the next day onwards.

An example of the flow of the game in this case will be described below. For example, first, the player deposits a valuable amount into the game value providing device by any method. The game value providing device subtracts a predetermined amount of valuable amount in response to the player's operation on any of the lending operation means, and provides the game value corresponding to the subtracted valuable amount to the pachislot machine 1. The player then plays the game, and repeats the above operation if more game value is required. Thereafter, when the player has acquired a predetermined amount of game value as a result of the game and wishes to end the game, the player operates any of the return operation means. The game value management device transmits the number of game values to the game value providing device in response to the player's operation on any of the return operation means. The game value providing device ejects a recording medium on which the transmitted number of game values is recorded. The game value management device clears the number of game values stored in itself when the game value number is transmitted. The player can take the ejected recording medium to a prize exchange office or the like to exchange it for a prize, or can move to another pachislot machine 1 and continue playing by inserting the ejected recording medium into a game value providing device corresponding to the other pachislot machine 1. Also, if the ejected recording medium is a member recording medium, it will remain valid from the next day onwards, so the player can stop playing here.

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, but it may be configured to transmit only the number of game values desired by the player depending on the manner of the player's return operation. In other words, it may be possible to divide the game value held by the player. Also, the game value providing device records the transmitted number of game values on a recording medium and discharges it, but it may transmit information of a similar value to the player's mobile terminal using the above-mentioned non-contact communication antenna, etc., and may also discharge, for example, cash or a cash equivalent, as long as it provides the player with something of equivalent value.

In addition, the pachislot machine 1 or the gaming value providing device may be provided with a lock operation means that can be operated by the player, and the gaming value management device and the gaming value providing device may be controlled to a state (locked state) in which communication between them is disabled in response to an operation on this lock operation means. In this case, the pachislot machine 1 or the gaming value providing device may be configured to perform authentication processes such as setting a PIN (and inputting the set PIN), issuing a one-time password (and inputting the issued one-time password), or biometric authentication, and the locked state may be released if the result of the authentication process is normal.

The medal-less gaming machine described so far, compared to when gaming media are physically provided for play, does not require some external structures such as the medal insertion port 5 and medal payout port 11, or some internal structures such as the selector 31 and hopper device 32, so not only can the cost and manufacturing costs of the gaming machine be reduced, but the power consumption of the gaming machine can also be reduced. Also, since it is 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 is improved and noise can be reduced. In other words, it is possible to provide a gaming machine that can improve various environments surrounding the gaming machine.

(Example of configuration of medal-less gaming machine)
Next, a configuration example of the pachislot machine 1 configured as a medal-less gaming machine will be described with reference to Fig. 34. Fig. 34 is a diagram showing an example of the configuration of a medal-less gaming machine. In the following, a configuration example in which a medal count control board (game value management device) is provided will be mainly described.

As described above, the medal count control board is connected to the main control board 71, and manages the number of medals (game value number) owned by the player. The medal count control board is also connected to a communication-only unit (game value providing device) via a connection terminal board (communication device). The medal count control board also transmits ball output management information to the ball output management device via the connection terminal board and the communication-only unit. The medal count control board is also equipped with a medal count control circuit (not shown). The medal count control circuit is also composed of, for example, a medal count control CPU (not shown), a medal count control ROM (not shown), and a medal count control RWM (not shown).

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

From this perspective, the medal count control board and the connection terminal board, like the main control board 71, perform important functions in the slot machine 1, and therefore must be provided inside the slot machine 1 in a manner that can prevent fraudulent acts and unauthorized modifications. Configuration example 1 and configuration example 2 shown in Figure 34 show examples of such a manner.

<Configuration Example 1>
Configuration example 1 shown in Fig. 34 shows that the medal count control board and the connection terminal board are housed in the main control board case, similar to the main control board 71. Here, the main control board case is usually subjected to various sealing processes to make it difficult to open (or remove) it, or to make it possible to recognize traces of opening (or the number of times it has been opened) (for example, sealing by crimping, affixing a sealing sticker, or affixing a crimping sticker that records that the crimping has been cut, etc.).

Therefore, by housing the medal count control board and the connection terminal board inside the main control board case, the same security effect as the main control board 71 can be obtained, and fraudulent acts and unauthorized modifications can be appropriately prevented.

<Configuration Example 2>
Configuration example 2 shown in Fig. 34 shows that the medal count control board and the connection terminal board are housed in a medal count control board case provided separately from the main control board case, unlike the above-mentioned configuration example 1. Note that the medal count control board case is configured as a resin case that is transparent (or nearly transparent) like the main control board case, and the medal count control board and the connection terminal board housed therein are housed in a state where they can be easily seen.

Here, the medal count control board case of configuration example 2 can be configured to undergo the same sealing process as the main control board case, or can be configured to undergo at least a portion of the sealing process. For example, the medal count control board case can be configured to be sealed by crimping like the main control board case, but without a sealing sticker. Also, for example, the main control board case may be required to use a predetermined crimp sticker, but the medal count control board case may be configured to allow the use of any sticker as the crimp sticker.

<Example of accumulated data>
The example of stored data shown in FIG. 34 shows an example of various data stored in the ball management device. That is, it shows an example of ball management information that the medal count control board transmits to the ball management device via the connection terminal board and the communication unit. Note that this is only an example, and it is possible to configure the device so that some of the various information shown in FIG. 34 is not transmitted, or to transmit information other than the various information shown in FIG. 34.

The timing at which the medal count control board transmits information to the communication-only unit may also be arbitrary, and the timing at which the communication-only unit transmits information to the ball payout management device may also be arbitrary. As long as the ball payout management device is capable of monitoring the ball payout performance of each gaming machine at least for each unit (e.g., each business day of an amusement facility), the information may be transmitted at any timing. For example, the timing at which the medal count 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 payout management device. Also, for example, the timing at which the medal count control board transmits information to the communication-only unit may differ depending on the type of information.

The accumulated data "total number of coins inserted" is the cumulative number of coins inserted per unit since each gaming machine was powered on. For example, the medal count control board transmits information on the number of game values bet by the player's betting operation, excluding those bets made by the replay operation, to the communication-only unit at a predetermined timing (e.g., for each unit of play), and the communication-only unit transmits the cumulative total of that information to the ball-out management device at a predetermined timing (e.g., when the gaming establishment closes for business).

The accumulated data "total number of payouts" is the cumulative number of payouts per unit since each gaming machine was powered on. For example, the medal count control board transmits information on the number of game values granted by the payout process of the gaming machine, excluding those granted by the replay operation, to the communication-only unit at a predetermined timing (e.g., for each unit of play), and the communication-only unit transmits the cumulative total of that information to the ball payout management device at a predetermined timing (e.g., when the gaming establishment closes for business).

The accumulated data "MY" is the maximum difference in number of coins that occurred during one unit after each gaming machine was powered on (in other words, the difference in number of coins obtained during the period in which the gaming value increased the most during one unit. This is referred to as "MY"). For example, the medal count control board calculates such a maximum difference in number of coins and transmits the calculated information to the communication-only unit at a predetermined timing (for example, when the gaming establishment closes for business), and the communication-only unit transmits the information to the ball-out management device at a predetermined timing (for example, when the gaming establishment closes for business).

The accumulated data "total number of coins paid out from game devices" is the cumulative number of coins paid out per unit since the power of each gaming machine was turned on, and is also the cumulative number of coins paid out while the various game devices are in operation. For example, the medal count control board transmits information on the number of game values awarded by the payout process of the gaming machine while the various game devices are in operation to the communication-only unit at a predetermined timing (for example, for each unit of play while the various game devices are in operation), and the communication-only unit transmits the cumulative total of that information to the ball-out management device at a predetermined timing (for example, at the closing time of the gaming establishment).

The accumulated data "total number of consecutive feature payouts" is the cumulative number of payouts per unit since each gaming machine was powered on, and is also the cumulative number of payouts paid out while the consecutive feature (RB, including RB when BB is in operation) is in operation. For example, the medal count control board transmits information on the number of game value awarded by the payout process of the gaming machine while the consecutive feature is in operation to the communication-only unit at a predetermined timing (for example, for each unit of play while the consecutive feature is in operation), and the communication-only unit transmits the cumulative total of that information to the ball payout management device at a predetermined timing (for example, at the end of business hours of the gaming establishment).

The medal count control board transmits various information that can be displayed on the role ratio monitor device 54 to the communication-only unit at a predetermined timing (for example, at the time of calculation by the role ratio monitor device 54), and the communication-only unit transmits the information to the ball management device at a predetermined timing (for example, at the time of transmission from the medal count control board). The accumulated data "role ratio" corresponds to, for example, the above-mentioned role ratio information, the accumulated data "continuous role ratio" corresponds to, for example, the above-mentioned continuous role ratio information, the accumulated data "advantageous zone ratio" corresponds to, for example, the above-mentioned specific zone ratio information, the accumulated data "instruction-included role ratio" corresponds to, for example, the above-mentioned role ratio information that is the subject of aggregation and calculation even during the AT state, and the accumulated data "role, etc. state ratio" corresponds to, for example, the above-mentioned specific zone ratio information that is the subject of aggregation and calculation even during the operation of various roles.

The accumulated data "number of plays" is the cumulative number of plays per unit since each gaming machine was powered on. For example, the medal count control board transmits information on the number of plays played to the communication-only unit at a predetermined timing (e.g., for each unit of play), and the communication-only unit transmits the cumulative total of that information to the ball payout management device at a predetermined timing (e.g., when the gaming establishment closes for business).

The stored data "main control chip ID number" is the individual identification number (also called "CPU ID", hereafter referred to as the "chip ID number") of the main control circuit 100 of each gaming machine. For example, when the medal count control board transmits various information to the communication-only unit, it transmits information including this individual identification number, and when the communication-only unit transmits various information to the ball management device, it transmits information including the transmitted individual identification number.

The stored 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 count control board transmits various information to the communication-only unit, it transmits information including this manufacturer code, and when the communication-only unit transmits various information to the ball output management device, it transmits information including the transmitted manufacturer code.

The stored 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 count control board transmits various information to the communication-only unit, it transmits information including this product code, and when the communication-only unit transmits various information to the ball output management device, it transmits information including the transmitted product code.

The stored data "medal count control chip ID number" is the individual identification number of the medal count control circuit of each gaming machine. For example, when the medal count 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 management device, it sends information including the individual identification number that was sent. Note that if there is no medal count control board and the main control board 71 is configured to send various information to the communication-only unit, the information will be "0".

The stored data "medal count control chip manufacturer code" is a manufacturer code recorded in the management area of the medal count control ROM of the medal count control circuit of each gaming machine. For example, when the medal count 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 management device, it sends information including the manufacturer code that was sent. Note that if a medal count control board is not provided and various information is sent to the communication-only unit by the main control board 71, the information will be "0".

The stored data "medal count control chip product code" is a product code recorded in the management area of the medal count control ROM of the medal count control circuit of each gaming machine. For example, when the medal count 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 information including the transmitted product code. Note that if a medal count control board is not provided and various information is transmitted to the communication-only unit by the main control board 71, the information will be "0".

In this way, the ball dispensing management device is capable of storing various information (ball dispensing management information) transmitted from gaming machines. The ball dispensing management information also includes multiple individual identification information (for example, the above-mentioned "main control chip ID number" to "medal count control chip product code") that can identify individual gaming machines. Therefore, the ball dispensing management device can identify the gaming machine that sent the information by these individual identification information, and if, for example, the correspondence between the "main control chip ID number" and the "medal count control chip ID number" changes from a certain point in time, it can recognize the possibility that one of the control boards has been replaced (i.e., the possibility that fraud or unauthorized modification has occurred).

The ball output management information also includes multiple pieces of ball output information (for example, the above-mentioned "total number of coins inserted" to "number of games played") that can identify the ball output performance per unit. Therefore, the ball output management device can use these pieces of ball output information to determine whether the gambling nature of the gaming machine that sent the information is within an appropriate range. For example, if the "total number of coins paid out" or the "ratio of instructed features" becomes significantly high from a certain point in time, it can determine the possibility that fraudulent activity or tampering has occurred, or that there was some kind of flaw in the original specification design.

If the ball output management device recognizes the above-mentioned possibility, it is expected that the result will be notified to the gaming facility or gaming machine manufacturer, etc., and appropriate measures will be taken. In other words, by constructing a management system that includes multiple managed gaming machines, a gaming value providing device (a communication-only unit) that transmits ball output management information transmitted from the managed gaming machines to the ball output management device, and a ball output management device that manages the ball output performance of each managed gaming machine based on the transmitted ball output management information, it becomes possible to appropriately manage all managed gaming machines under management.

<Modification 1>
As described above, in a medalless gaming machine, the medal count control board can be configured to manage the number of game values owned by a player. Therefore, in order to allow the manager of the gaming facility to grasp such management status or other information, a medal count monitor device (not shown) may be provided on the medal count control board.

The medal count monitor device is, for example, configured with a four-digit seven-segment LED, and is provided inside the medal count control board case. The medal count monitor device sequentially displays various information (for example, part or all of the above-mentioned ball payout management information) related to the game value number tallied and calculated by the medal count control CPU (or it may be the main CPU 101). Note that if all of the display contents of the role ratio monitor device 54 are displayed by the medal count monitor device, the role ratio monitor device 54 may not be provided. Alternatively, the role ratio monitor device 54 may be configured to be used in combination with the medal count monitor device.

The medal count monitor device may be mounted on the medal count control board, or on another board (e.g., a connection terminal board) connected to the medal count control board. It may also be provided in another location within the cabinet G. For example, it may be provided on the medal count control board case. A management switch for starting the display on the medal count monitor device or for switching its contents may be provided within the cabinet G, and various information may be displayed when this switch is operated. Assuming that such a management switch is used, for example, the information display device 14 may be configured to be used in combination with the medal count monitor device.

The medal count monitor device may display the type of error state that has occurred when any of the various error states related to the device occur. For example, if a communication error occurs with the main control board 71, if a communication error occurs with the connection terminal board, if a communication error occurs with the gaming value providing device, or if an abnormality occurs in the medal count control RWM, a numerical value corresponding to the error may be displayed. In this case, an explanation section (such as a sticker or printing) indicating the correspondence may be provided on or near the medal count control board case so that the manager of the gaming facility can easily recognize which error state the displayed numerical value corresponds to.

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

For example, the connection terminal board and the external centralized terminal board 55 are configured as a common terminal board. This not only reduces the number of parts, but also reduces the amount of wiring to the outside, thereby improving security.

For example, the connection terminal board and the external centralized terminal board 55 are configured as one unit. For example, the connection terminal board and the external centralized terminal board 55 are arranged in close proximity at least within the cabinet G. This can improve the efficiency of the connection process. Also, the length of the wiring can be kept constant, and the wiring locations can be limited, improving security.

<Modification 3>
As described above, the medalless gaming machine can be configured to transmit ball-discharge management information to the ball-discharge management device. The ball-discharge management device can appropriately manage the ball-discharge performance of each medalless gaming machine by the transmitted ball-discharge management information. Therefore, on the premise that the ball-discharge performance can be appropriately managed in this manner, the above-mentioned limiter may not be provided. In other words, the device may not have a function of forcibly terminating the advantageous zone based on the establishment of a certain regulation condition.

In addition, the medal count control board may be provided with a function for appropriately managing the ball output performance, and on the assumption that the ball output performance can be appropriately managed in this way, the above-mentioned limiter may not be provided. In other words, it may not have a function for forcibly ending the advantageous zone based on the establishment of certain regulatory conditions.

For example, the medal count control board is configured to include a ball output monitoring RWM (which may be the medal count control RWM described above or a different RWM). The ball output monitoring RWM is initialized, for example, when the setting is changed, but is not initialized when the favorable zone ends, so as to monitor the ball output. When the monitored ball output exceeds a certain threshold, for example, the favorable zone itself is not forcibly ended, but the control may be performed to reduce the ball output performance by lowering the probability of navigation occurrence, lowering the probability that the AT state is extended, or ending the AT state itself. In this way, it is possible to appropriately manage the ball output performance. In this case, such control results may be transmitted to the ball output management device as ball output management information. In other words, the ball output performance of each medal-less gaming machine may be managed in both the medal count control board and the ball output management device.

(Example of the main control board configuration of a pachinko slot machine)
Next, a configuration example of the main control board 71 of the slot machine 1 will be described with reference to Fig. 35. Fig. 35 is a diagram showing an example of the configuration of the main control board 71. In the following, a configuration example of the reuse of the main control board 71 will be mainly described.

As mentioned above, there are various restrictions on the specifications of the main control board 71 in the pachislot machine 1, one of which is that the manufacturer's name and board control number must be printed on the main control board 71. The manufacturer's name is the name of the gaming machine manufacturer that produces the pachislot machine 1, and the control number is a number that identifies the model of the main control board 71.

<Configuration Example 1>
Configuration example 1 shown in FIG. 35 shows that the manufacturer name and the board management number are printed in characters on the main control board 71 as in the past. Here, in configuration example 1 shown in FIG. 35, first, a slot machine 1 (hereinafter described as "model A") on which the main control board 71 is mounted is manufactured by BB Co., Ltd. At this time, initially, only the manufacturer name "BB Co., Ltd." and the board management number "BB-00-11-22" in the lower row are printed. After that, if model A is removed from the game store and, for example, AA Co., Ltd. tries to reuse the main control board 71 to manufacture a different slot machine 1 (hereinafter described as "model B"), AA Co., Ltd. must erase the manufacturer name and board management number printed in the lower row by laser engraving and newly print the manufacturing number and board management number related to its own company in a different space (for example, the manufacturer name "AA Co., Ltd." and the board management number "AA-00-11-22" in the upper row of configuration example 1 shown in FIG. 35).

Then, if model B is subsequently removed from the gaming establishment, and, for example, BB Co., Ltd. were to reuse the main control board 71 to manufacture a different pachislot machine 1 (hereinafter referred to as "model C"), BB Co., Ltd. would have to remove the manufacturer's name and board control number printed on the top line by laser engraving, and print a new manufacturing number and board control number related to their company in a different space. However, since there is no more free space in configuration example 1 shown in FIG. 35, there is a problem in that, even though the hardware is still fully reusable, the main control board 71 may not be able to be reused due to the constraints mentioned above.

This is also true in cases where multiple manufacturer names and board control numbers have been printed on the machine from the beginning. For example, even if the serial numbers and board control numbers for both AA Co., Ltd. and BB Co., Ltd. are printed on the machine in advance, the serial numbers and board control numbers for AA Co., Ltd. are erased by laser engraving when Model A is manufactured. Therefore, while BB Co., Ltd. may be able to reuse the machine, AA Co., Ltd. will not be able to reuse it. In contrast, the following configuration examples 2 and 3 are expected to solve the above-mentioned problems. In other words, the reusability of boards used to control games, such as the main control board 71, can be increased.

<Configuration Example 2>
Configuration example 2 shown in Fig. 35 shows that a code including the manufacturer's name and the board control number is printed. 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 the code including the manufacturer's name and the board control number, but a JAN code (bar code) or other code can be used. In other words, the code may be any code as long as it includes information that allows a checker to uniquely identify the manufacturer's name and the board control number by some means (for example, a mobile terminal, etc.).

In configuration example 2 shown in FIG. 35, first, when model A is assumed to have been manufactured by BB Co., Ltd., the first code from the right is printed. The first code from the right contains information that can identify the manufacturing number and board management number related to BB Co., Ltd. After that, when model A is removed from the gaming facility and, for example, AA Co., Ltd. attempts to manufacture model B, the second code from the right is printed and the first code from the right is erased by laser engraving. The second code from the right contains information that can identify the manufacturing number and board management number related to AA Co., Ltd.

After that, when model B is removed from the gaming establishment and, for example, BB Co., Ltd. attempts to manufacture model C, the third code from the right is printed and the second code from the right is erased by laser engraving. The third code from the right contains information that can identify the manufacturing number and board management number of BB Co., Ltd. After that, even when model C is removed from the gaming establishment and, for example, AA Co., Ltd. attempts to reuse the main control board 71 to manufacture a different pachislot machine 1, AA Co., Ltd. can erase the third code from the right by laser engraving and print the fourth code from the right, so that the fourth code from the right contains information that can identify the manufacturing number and board management number of AA Co., Ltd., and thus it becomes possible to reuse the main control board 71 in an even newer pachislot machine 1.

In other words, in configuration example 2 shown in FIG. 35, by printing a code including the manufacturer's name and board control number, it is possible to save the printing space for each manufacturer's name and board control number on the surface of the main control board 71, making it possible to increase the reusability compared to configuration example 1 shown in FIG. 35.

<Configuration Example 3>
Configuration example 3 shown in FIG. 35 shows that a code including a manufacturer name and a board management number is printed, similarly to configuration example 2 described above. Note that in configuration example 3 shown in FIG. 35, multiple codes (for example, four) are printed from the beginning. For example, two codes are printed for each of AA Co., Ltd. and BB Co., Ltd. In addition, on the surface of the main control board 71 (or on the corresponding main control board case), the parts corresponding to each code are crimped with, for example, a strip-shaped member, etc., so that the codes can be fixed in an unreadable state. In addition, for example, by cutting the strip-shaped member, etc., the fixation can be released to make the codes readable.

In configuration example 3 shown in FIG. 35, first, when model A is manufactured by BB Co., Ltd., only the first code from the right is made readable, and the second to fourth codes from the right are made unreadable. The first code from the right contains information that can identify the manufacturing number and board management number related to BB Co., Ltd. After that, when model A is removed from the gaming facility and, for example, AA Co., Ltd. attempts to manufacture model B, only the second code from the right is made readable, and the first, third, and fourth codes from the right are made unreadable. The second code from the right contains information that can identify the manufacturing number and board management number related to AA Co., Ltd.

After that, when model B is removed from the gaming establishment and, for example, BB Co., Ltd. attempts to manufacture model C, only the third code from the right is made readable, and the first, second, and fourth codes from the right are made unreadable. The third code from the right contains information that can identify the manufacturing number and board management number of BB Co., Ltd. After that, when model C is removed from the gaming establishment and, for example, AA Co., Ltd. attempts to reuse the main control board 71 to manufacture a different pachislot machine 1, AA Co., Ltd. can make only the fourth code from the right readable and the first through third codes from the right unreadable, thereby making it possible to reuse the main control board 71 in an even new pachislot machine 1.

In addition, in configuration example 3 shown in FIG. 35, since it is sufficient to make at least one code readable and the other codes unreadable, further reuse is possible, and it is also possible for the machine to be reused by a greater number of gaming machine manufacturers. Note that configuration example 3 shown in FIG. 35 can also be configured so that only crimping holes are provided, and the code is printed in the location corresponding to the crimping hole each time the machine is reused.

[10. Second gaming machine]
Next, referring to Figures 36 to 93, another specific example of the configuration of a pachislot machine will be described as a "second gaming machine." In addition, the second gaming machine (this embodiment) is not a gaming machine in which a game is played using medals as in the past, but a gaming machine in which the number of game media used for the game to be lent, the number of reserved (number of credits), the number of inserted (number of bets), the number of paid out, the number of settlements, etc. are electromagnetically managed (managed by electronic data), a so-called medal-less gaming machine (CR gaming machine) will be described.

[10-1. Configuration of gaming system]
Next, the configuration of a gaming system including a slot machine, which is a second gaming machine that can be played without medals, will be described with reference to Fig. 36. Fig. 36 is a perspective view showing the external structure of the gaming system including the slot machine of this embodiment.

As shown in FIG. 36, the gaming system 400 is composed of a pachinko slot machine 401 and peripheral devices (processing devices) including a gaming media lending device 402 (sand device or CR sandwich) that is connected to the pachinko slot machine 401 so that various data can be input and output. The peripheral devices include not only the gaming media lending device 402, but also peripheral devices 500 (see FIG. 39 described below) such as a data display that displays data such as the number of times a game has been played and the number of times a bonus has been won.

Although not shown in FIG. 36, the game media lending device 402 and the peripheral device 500 are connected to the management computer (hall computer) of the amusement facility so that data can be transmitted thereto. Specifically, the game media lending device 402, the peripheral device 500, and other peripheral devices are connected to the management computer via a LAN (Local Area Network) line (Ethernet (registered trademark)).

In addition, in the pachislot 401, as described below, various processes related to the management of the number of gaming media (number of medals), such as the process of counting the number of accumulated gaming media (gaming value), the process of inserting (betting), the process of paying out, and the process of settling, are performed by a medal count control board 443 (described later, see FIG. 39 ) provided inside the pachislot 401, and the gaming media lending device 402 mainly performs processes related to the lending of gaming media (management of the number of loaned medals). However, the present invention is not limited to this, and some or all of the various processes related to the management of the number of gaming media performed by the medal count control board 443 described later may be performed by the gaming media lending device 402. In other words, a gaming media management device may be used instead of the gaming media lending device 402.

[10-2. Appearance structure]
As shown in Fig. 36, the slot machine 401 includes a cabinet 411a (not shown) (see Fig. 38 described later) that houses reels and various circuit boards, and a front door 411b that is attached to the cabinet 411a so as to be able to open and close. Inside the cabinet 411a, three reels 412L, 412C, and 412R (variable display means, display row) are provided, and the three reels 412L, 412C, and 412R are arranged in a row in the horizontal direction (direction perpendicular to the direction of rotation of the reels). Hereinafter, the reels 412L, 412C, and 412R are also referred to as the left reel 412L, the center reel 412C, and the right reel 412R, respectively.

Each reel has a cylindrical reel body and a translucent sheet material attached to the circumferential surface (rotating surface) of the reel body. On the surface of the sheet material, multiple (e.g. 21) patterns are drawn at a predetermined interval along the circumferential direction of the reel body (the direction of rotation of the reel).

A display device 413 (display means) is provided in the approximate center of the front door 411b. The display device 413 has a display screen including three symbol display areas 414L, 414C, and 414R. In the pachislot 401 of this embodiment, images are displayed and effects are executed using the entire display screen including the symbol display areas 414L, 414C, and 414R.

The three symbol display areas 414L, 414C, and 414R are provided corresponding to the left reel 412L, the center reel 412C, and the right reel 412R, respectively. As shown in FIG. 36, each symbol display area is provided in a position overlapping with the corresponding reel when viewed from the front (player side), and is provided so as to be located in front (player side) of the corresponding reel. Each symbol display area functions as a display window, and the symbol drawn on the corresponding reel provided behind it can be viewed through the display window. Hereinafter, the symbol display areas 414L, 414C, and 414R are also referred to as the left display window 414L, the center display window 414C, and the right display window 414R, respectively.

In addition, in this embodiment, each display window is configured so that when the rotation of the corresponding reel behind it stops, it can display three consecutively arranged patterns out of the multiple types of patterns depicted on the reel. In other words, within the frame of each display window, upper, middle, and lower areas are provided, and one pattern can be displayed in each area. Therefore, in this embodiment, patterns can be displayed in a 3x3 array on the display screen of display device 413.

In this embodiment, in the patterns displayed in a 3x3 array, a pseudo line set across from the left display window 414L (left reel 412L) to the right display window 414R (right reel 412R) is defined as a line (hereinafter referred to as a "active line") that determines whether or not a win has been won. For example, a pseudo line (center line) set across the middle area of the left display window 414L, the middle area of the center display window 414C, and the middle area of the right display window 414R can be set as an active line. Note that the setting of the active line is not limited to this example and can be set arbitrarily.

A seven-segment display 415a consisting of a seven-segment LED (Light Emitting Diode) and a bet lamp 415b are provided near the side edges of the display screen of the display device 413. The seven-segment display 415a digitally displays information such as the number of game media inserted in the current game (hereinafter referred to as the "input number" or "bet number"), the number of game media paid out to the player as a bonus (hereinafter referred to as the "payout number"), and the number of game media deposited inside the pachislot 401 (hereinafter referred to as the "reserved number" or "credit number"). The bet lamp 415b lights up lamps with numbers ("1" to "3" in FIG. 36) corresponding to the number of game media inserted. The display control of the display device 413, the seven-segment display 415a, and the bet lamp 415b is controlled by the sub-control board 442 (see FIG. 39) described later.

In addition, various devices (various operating means) to be operated by the player are provided below the display device 413 of the front door 411b (the base and its surrounding area), as shown in FIG. 36. Specifically, the pachislot 401 of this embodiment is provided with a MAX BET button 416, a 1 BET button 417, a settlement button 418, a loan button 419, a return button 420, a card return button 421, a start lever 422, stop buttons 423L, 423C, 423R, an operation button 424, and a performance button 425.

The MAX BET button 416 and the 1 BET button 417 are operation buttons used to determine the number of gaming media (number of bets) to be used in one game from the number of gaming media stored (number of credits) managed by electronic data in the pachislot 401. The MAX BET button 416 is a bet button used to insert (bet) the number of gaming media required for one game (hereinafter referred to as the "maximum specified number": "3" in this embodiment) with a single press. The 1 BET button 417 is a bet button used to insert (bet) "1" gaming medium with a single press. Therefore, when using the 1 BET button 417 to insert the gaming media required for one game, the 1 BET button 417 is pressed three times.

When a player presses the MAX BET button 416 when performing a bet operation (processing) on gaming media, the number of gaming media inserted required for one game (the maximum specified number "3") is subtracted from the number of gaming media stored in the electronic data (the gaming media is consumed). On the other hand, when a player presses the 1 BET button 417 when performing a bet operation (processing) on gaming media, the number of gaming media stored in the electronic data is subtracted by 1.

In addition, inside each of the MAX BET button 416 and 1 BET button 417, there is a BET button LED (not shown) that lights up when it is possible to insert gaming media (bet operation) using each BET button.

The settlement button 418 is an operation button used when withdrawing (settling) game media stored inside the pachislot 401 to the outside. When the player presses the settlement button 418 at the time of settling the game media, the number of game media stored in the pachislot 401 managed as electronic data is written to a game card (not shown) inserted in the game media lending device 402, and the number of game media stored in the pachislot 401 becomes zero.

The loan button 419 is an operation button used when the player inserts additional gaming media. When the player presses the loan button 419, a predetermined number of gaming media are added from the number of gaming media remaining on the gaming card (not shown) inserted in the gaming media loan device 402 (hereinafter referred to as "degrees") to the number of gaming media stored in the slot machine 401 managed by electronic data. Also, for example, when the player inserts cash into the gaming media loan device 402 and presses the loan button 419, the number of gaming media corresponding to the amount inserted is added to the degree of the gaming card or the number of gaming media stored in the slot machine 401.

The return button 420 is an operation button used to withdraw gaming media that have already been inserted in the current game (to cancel a bet operation). When the player presses the return button 420, the number of gaming media that have already been bet (the number inserted) is returned (added) to the number of stored gaming media, and the number of inserted gaming media becomes 0.

The card return button 421 is an operation button used to remove a gaming card (not shown) inserted into the gaming media lending device 402. When the player presses the card return button 421, the number of gaming media stored and the number of gaming media inserted that have been bet, which are managed in the pachislot 401, are added to the degree of the gaming card, and then the gaming card is ejected from the gaming media lending device 402.

The start lever 422 is an operating lever that is used to start a game after a bet operation on a gaming medium is completed. When the start lever 422 is operated (pressed) by the player, all reels (412L, 412C, 412R) start to rotate.

The stop buttons 423L, 423C, and 423R correspond to the left reel 412L, center reel 412C, and right reel 412R, respectively, and each stop button is an operation button used to stop the rotation of the corresponding reel. Hereinafter, the stop buttons 423L, 423C, and 423R are also referred to as the left stop button 423L, the center stop button 423C, and the right stop button 423R, respectively.

Operation button 424 is an operation button used when configuring various settings related to the effects. Moreover, effect button 425 is an operation button known as a PUSH button, and is an operation button that is operated by the player as necessary during play in accordance with the effects related to the game.

In addition, as shown in FIG. 36, a game information display unit 426a, a medal count display unit 426b (game value display means), and a medal lending display unit 427a are provided at the bottom (base and surrounding area) of the display device 413 of the front door 411b, which display various information related to the current game operation and the number of game media. The medal lending display unit 427a is a display panel mounted on the medal lending operation board 427 (see FIG. 39, described below). In addition, the game information display unit 426a, medal count display unit 426b, and medal lending display unit 427a provided on the base are each covered by a transparent window cover (not shown).

The game information display unit 426a is electrically connected to the main control board 441 via the door relay board 444 described later, and the display operation of various game information on the game information display unit 426a is controlled by a main control microprocessor 450 (main control circuit) described later in the main control board 441. The medal count display unit 426b is electrically connected directly to the medal count control board 443 described later, and the display operation of the medal count (credit count) on the medal count display unit 426b is controlled by a medal count control microprocessor 460 (medal count control circuit) described later in the medal count control board 443. The medal lending operation board 427 described later is electrically connected to the game medium lending device 402 via the game ball etc. connection terminal board 445 described later, so the display operation of the medal lending display unit 427a is controlled by a peripheral device control unit 402a (see FIG. 49 described later) in the game medium lending device 402.

Here, Figures 37A, 37B, and 37C respectively show configuration examples of the game information display unit 426a, medal count display unit 426b, and medal lending display unit 427a.

As shown in FIG. 37A, the game information display unit 426a is provided with a two-digit seven-segment LED for digitally displaying (informing) the player of the number of game media paid out.

In addition, the game information display unit 426a is provided with LEDs (hereinafter referred to as "line LEDs") for displaying the number of bets, indicated as "START", "REPLAY", "1 BET", "2 BET", and "3 BET" in FIG. 37A, as lamps that indicate game operation information.

For example, when the number of gaming media bets (number of inserted coins) is 0 (all line LEDs are off), pressing the 1 bet button 417 lights up the "1 BET" line LED, and when the 1 bet button 417 is pressed again, the "1 BET" and "2 BET" line LEDs light up, and when the 1 bet button 417 is pressed again, all the line LEDs "1 BET" to "3 BET" light up and the "START" line LED lights up. At this time, each time the 1 bet button 417 is pressed, the value of the number of accumulated gaming media (number of credits) displayed by the 5-digit 7-segment LED described below in the medal count display unit 426b is decremented by 1.

For example, when the number of gaming media bets (number of inserted coins) is 0 (all line LEDs are off), pressing the MAX BET button 416 causes all of the line LEDs for "1 BET" to "3 BET" to light up, as well as the "START" line LED. At this time, with one bet operation, the value of the number of gaming media stored (number of credits) displayed by the 5-digit 7-segment LED described below in the medal count display unit 426b is reduced by 3.

Furthermore, for example, if a replay role is won in the previous game, the "START" and "REPLAY" line LEDs will light up. At this time, the value of the number of game media stored (number of credits) displayed on the 5-digit 7-segment LED described below in the medal count display unit 426b will not be subtracted.

The game information display unit 426a is also provided with an instruction display section (instruction monitor) that notifies the player of information on the reel stopping operations required to display along the winning line the symbol combination corresponding to the role determined as the internal winning role. The instruction display section is composed of a three-digit seven-segment LED. The instruction display section notifies the player of the necessary stopping operation information by controlling the display content of the three-digit seven-segment LED in a manner that uniquely corresponds to the notified stopping operation information.

Note that the aspect that uniquely corresponds to the information on the stop operation being notified means, for example, displaying the number "1" on the instruction display section when notifying the push order (left 1st) for the first stop operation on the left reel 412L (left stop button 423L), displaying the number "2" on the instruction display section when notifying the push order (middle 1st) for the first stop operation on the center reel 412C (middle stop button 423C), and displaying the number "3" on the instruction display section when notifying the push order (right 1st) for the first stop operation on the right reel 412R (right stop button 423R).

In addition, in the pachislot 401 of this embodiment, in addition to the instruction display unit controlled by the main control board 441, a configuration may be provided in which information on the stop operation is notified using other means controlled by the sub-control board 442 described below. For example, information on the stop operation may be notified by the display device 413.

When such a configuration is applied, the mode of notification in the instruction display unit and the mode of notification in other means controlled by the sub-control board 442 may be different from each other. In other words, the instruction display unit only needs to notify in a manner that uniquely corresponds to the information of the stop operation to be notified, and does not necessarily need to notify the information of the stop operation directly (for example, even if the number "1" is displayed on the instruction display unit, some players may not be able to identify the content of the notification, and it cannot be said to be a direct notification). On the other hand, in notifications on the sub side (sub-control board 442 side) by other means such as the display device 413, the information of the stop operation may be directly notified. For example, when notifying the push order "left 1st", the instruction display unit displays the number "1" that uniquely corresponds to the push order to be notified, but other means (for example, the display device 413, etc.) may directly notify the instruction information for performing the first stop operation on the left reel 412L.

In a pachislot 401 configured in this way, necessary information on the stopping operation according to the internal winning combination can be notified not only by control of the sub-control board 442 but also by control of the main control board 441. Furthermore, whether or not such information on the stopping operation is notified may be controlled according to the gaming state. For example, information on the stopping operation may not be notified in the general gaming state (non-ART gaming state), but may be notified in the ART gaming state.

As shown in FIG. 37B, the medal count display unit 426b is provided with a 5-digit 7-segment LED for digitally displaying (informing) to the player information such as the number of gaming media stored (number of credits) inside the pachislot 401. Note that in this embodiment, a 2-digit 7-segment LED for displaying the number of gaming media stored (number of credits) provided in conventional gaming machines may be provided separately from the 5-digit 7-segment LED for displaying credits shown in FIG. 37B. The 5-digit 7-segment LED for displaying credits may also be provided in the gaming media lending device 402.

Furthermore, the medal count display unit 426b is provided with a one-digit seven-segment LED (error display means) for digitally displaying (notifying) to the player any errors (such as an upper limit exceeding error or an upper limit exceeding notice error, as described below) related to the control of the medal count (number of credits) managed by the medal count control board 443. When an error occurs related to the control of the medal count (number of credits) managed by the medal count control board 443, an error code (such as a letter or number) corresponding to the type of error is displayed by this one-digit seven-segment LED for error display. When such a one-digit seven-segment LED for error display is provided, an error display means dedicated to the management control of the medal count (game value) is provided, so that, for example, there is no confusion between errors related to the management control of the medal count and other errors, and it is easy to recognize that an error related to the management control of the medal count has occurred.

As shown in FIG. 37C, the medal lending display unit 427a separately displays information indicating the number of points on the gaming card (remaining number of gaming media), whether the gaming media can be lent or not, and whether the gaming media can be returned or not.

In this embodiment, the degree of the gaming card is displayed numerically by a three-digit seven-segment LED. The lamp for the lending operation (the "Lend" lamp in FIG. 37C) is an LED (gaming medium lendable LED) that notifies whether or not the gaming medium can be lent. When the gaming medium can be lent (before the lending operation), the lamp for the lending operation is lit, and when the gaming medium cannot be lent (during lending, during settlement, during return, during an abnormality), the lamp for the lending operation is turned off. The lamp for the return operation (the "Return" lamp in FIG. 37C) is an LED (gaming medium returnable LED) that notifies whether or not the gaming medium can be returned. When the gaming medium can be returned (before the return operation), the lamp for the return operation is lit, and when the gaming medium cannot be returned (during lending, during settlement, during return, during an abnormality), the lamp for the return operation is turned off.

In this embodiment, dynamic lighting control is used as the control method for the various 7-segment LEDs provided in the game information display unit 426a, medal count display unit 426b, and medal lending display unit 427a.

Furthermore, as shown in FIG. 36, the front door 411b is provided with a lamp 428 and speakers 429L, 429R, etc. The lamp 428 is composed of an LED or the like, and turns on/off the light in a pattern corresponding to the performance content. Furthermore, the speakers 429L, 429R output sounds such as sound effects and music corresponding to the performance content.

As shown in FIG. 36, the game media lending device 402 is installed on the right side wall of the slot machine 401 when viewed from the front (player side). A bill slot 406, a coin slot 407, a game card slot 408, etc. are provided on the front of the housing 405 of the game media lending device 402.

[10-3. Internal structure]
Next, the internal structure of the slot machine 401 will be described with reference to Fig. 38. Fig. 38 shows the state in which the front door 411b is open, and shows the structure of the rear side of the front door 411b and the cabinet 411a. The internal structure is shown.

A main control board 441 mounting a main control microprocessor 450 (see FIG. 41) described below is provided in the upper part of the cabinet 411a. The main control microprocessor 450 described below is a circuit that controls the main operations of the game in the pachislot 401 and the flow between these operations, such as determining the internal winning combination, spinning and stopping each reel, and determining whether or not a prize has been won. The specific configuration of the main control microprocessor 450 will be described later.

Three reels (left reel 412L, middle reel 412C, and right reel 412R) are provided in the center of cabinet 411a. Although not shown, each reel is connected to a corresponding stepping motor via a gear having a predetermined reduction ratio.

A sub-control board 442 is provided inside the cabinet 411a on the side of the left reel 412L opposite the center reel 412C (the left side in the example shown in FIG. 38). Although not shown, the sub-control board 442 is equipped with a control circuit and the like for controlling the execution of effects such as the display of images. A power supply unit 430 is provided in the lower part of the cabinet 411a to supply the necessary power to each device of the slot machine 401.

Although not shown in FIG. 38, the pachislot 401 is provided with various boards (including a medal count control board 443) in addition to the main control board 441 and sub-control board 442 (see FIG. 39 below), and each board is installed in a suitable position within the cabinet 411a or on the back side of the front door 411b according to its function (purpose) and the structure of the housing.

[10-4. Control system of gaming system]
[10-4-1. Configuration of gaming system]
Next, a control system provided in the gaming system 400 will be described with reference to Fig. 39. Fig. 39 is a circuit block diagram showing the configuration of the control system of the gaming system 400.

The slot machine 401 has a main control board 441 and a sub-control board 442. The slot machine 401 also has a medal count control board 443, a door relay board 444, a setting key switch 432 (setting switch), a reset switch 433, a reel unit 412, and a power supply unit 430, all of which are connected to the main control board 441. Note that in FIG. 39, the main control board 441 and medal count control board 443 are surrounded by dashed lines, which means that the main control board 441 and medal count control board 443 may be configured as a single board (main control board).

The pachislot 401 also has a door open/close monitor switch 431, a stop switch board 423 (stop switch), a MAXBET switch 416S, a 1BET switch 417S, a return switch 420S, a start switch 422S, and a game information display unit 426a, all of which are connected to the main control board 441 via a door relay board 444.

The slot machine 401 also has a game ball connection terminal board 445, a medal lending operation board 427, a settlement switch 418S, a medal count clear switch 443a (predetermined operation detection means), and a medal count display unit 426b, all of which are connected to the medal count control board 443. The medal count control board 443 is also connected to the power supply device 430. The slot machine 401 also has a lending switch 419S and a card return switch 421S, which are connected to the medal lending operation board 427.

The slot machine 401 has a display device 413 and a sub-relay board 446 connected to a sub-control board 442. The sub-control board 442 is also connected to a power supply 430. The slot machine 401 also has an operation switch 424S, a performance switch 425S, an LED drive board 434, and a speaker group 429 connected to the sub-control board 442 via the sub-relay board 446. The sub-control board 442 is also connected to the reel unit 412 via the sub-relay board 446. The slot machine 401 also has an LED group 435 connected to the LED drive board 434, which is controlled to turn on and off during a performance.

In the gaming system 400 of this embodiment, the peripheral device control unit 402a (see FIG. 49 described later) of the gaming medium lending device 402 is connected to the medal count control board 443 via the gaming ball etc. connection terminal board 445 in the slot machine 401. The medal lending operation board 427 is also connected to the peripheral device control unit 402a (see FIG. 49 described later) of the gaming medium lending device 402 via the gaming ball etc. connection terminal board 445, and the display operation of the medal lending display unit 427a when the lending switch 419S is pressed is controlled by the peripheral device control unit 402a (see FIG. 49 described later) of the gaming medium lending device 402. In addition, input and output of a gaming medium lending enable signal is performed between the medal count control board 443 and the medal lending operation board 427.

[10-4-2. Components of the gaming machine (Pachislot 401)]
Next, we will explain the configuration and function of each part of the pachislot 401. The configurations of the main control board 441 and the medal count control board 443 will be described in detail later.

The door relay board 444 is a relay board on which wiring is implemented that connects the main control board 441 to the various switches and the game information display unit 426a.

The setting key switch 432 is provided, for example, in a case that houses the main control board 441. The setting key switch 432 is used when changing the settings of the pachislot 401 (for example, settings 1 to 6) or when checking the settings of the pachislot 401. The reset switch 433 is used, for example, when changing the settings of the pachislot 401.

The reel unit 412 includes a left reel 412L, a center reel 412C, a right reel 412R, a stepping motor (not shown) for driving each reel to rotate, a reel backlight (not shown), etc. The turning on/off operation of the reel backlight is mainly controlled by the sub-control board 442 during the performance.

The power supply device 430 has a power supply board 430b and a power switch 430a connected to the power supply board 430b. The power switch 430a is pressed when supplying the necessary power to the slot machine 401.

The door opening/closing monitoring switch 431 is disposed on the rear surface of the front door 411b, detects whether the front door 411b is open or closed, and outputs a security signal to the outside of the slot machine 401 to notify the opening or closing.

The stop switch board 423 is equipped with a circuit for stopping the spinning reels and a circuit for indicating which reels can be stopped using an LED or the like. The stop switch board 423 is also provided with a stop switch (not shown). The stop switch detects when each stop button 423L, 423C, 423R is pressed by the player (stop operation).

The MAX BET switch 416S detects that the MAX BET button 416 has been pressed by the player, and outputs the detection signal to the main control board 441 via the door relay board 444. The 1 BET switch 417S detects that the 1 BET button 417 has been pressed by the player, and outputs the detection signal to the main control board 441 via the door relay board 444.

The return switch 420S detects that the return button 420 has been pressed by the player, and outputs the detection signal to the main control board 441 via the door relay board 444. The start switch 422S detects that the start lever 422 has been operated by the player (start operation), and outputs the detection signal to the main control board 441 via the door relay board 444.

The game information display unit 426a is connected to the main control board 441 via the door relay board 444, and displays various game information output from the main control board 441. The medal count display unit 426b is connected to the medal count control board 443, and displays information on the number of credits output from the medal count control board 443.

The game ball etc. connection terminal board 445 is not shown in FIG. 39, but is a board on which a connection mechanism part 445a (see FIG. 90A described below) is mounted for connecting the game medium lending device 402 to the medal count control board 443, and for connecting the peripheral device 500 such as a data display to the medal lending operation board 427.

Note that, although not shown, a connection circuit (contact input/output circuit) made up of a photocoupler is provided on each connection wiring in the connection mechanism unit 445a to suppress the effects of noise from outside. In addition, the connection mechanism unit 445a is provided with a connector (25-pin connection connector) made up of multiple connection pins that is connected to the game medium lending device 402 via a harness.

The medal lending operation board 427 is a board on which the medal lending display unit 427a is mounted.

The settlement switch 418S detects that the settlement button 418 has been pressed by the player, and outputs the detection signal to the medal count control board 443. The lending switch 419S detects that the lending button 419 has been pressed by the player, and outputs the detection signal to the gaming medium lending device 402 via the medal lending operation board 427 and the gaming ball etc. connection terminal board 445. The card return switch 421S detects that the card return button 421 has been pressed by the player, and outputs the detection signal to the gaming medium lending device 402 via the medal lending operation board 427 and the gaming ball etc. connection terminal board 445.

The medal count clear switch 443a is a switch that is pressed (predetermined operation) when an attendant of the gaming establishment clears the medal count (credit count) stored in the slot machine 401. The medal count clear switch 443a is electrically connected to a medal count control microprocessor 460 described later, and when a pressing operation is performed on the medal count clear switch 443a, the pressing operation is detected and the detection signal (medal count clear signal) is output to the medal count control microprocessor 460 described later. Note that the medal count control microprocessor 460 described later to which the medal count clear signal is input controls the medal count display unit 426b based on the medal count clear signal so that the display of the 5-digit 7-segment LED for credit display (see FIG. 37B) provided in the medal count display unit 426b becomes "00000" (credit count = 0).

The medal count clear switch 443a is directly mounted on the medal count control board 443. In the slot machine 401 of this embodiment, the main control board 441 and the medal count control board 443 are stored in separate control board cases. Here, referring to FIG. 40, an example of mounting the medal count clear switch 443a on the medal count control board 443 and an example of storing the main control board 441 and the medal count control board 443 in the control board case will be described. FIG. 40A is a diagram showing the mounting state of the control microprocessor on each board of the main control board 441 and the medal count control board 443, FIG. 40B is a diagram showing the storage state of the main control board 441 and the medal count control board 443 in the board case, and FIG. 40C is a diagram showing another storage state of the main control board 441 and the medal count control board 443 in the control board case.

In the slot machine 401 of this embodiment, as shown in FIG. 40A, the main control board 441 is equipped with a main control microprocessor 450 described later, and the medal count control board 443 is equipped with a medal count control microprocessor 460 and medal count clear switch 443a described later. As shown in FIG. 40B, the main control board 441 is stored in a dedicated main control board case 481, and the medal count control board 443 is stored in a dedicated medal count control board case 482. In addition, the medal count control board case 482 is formed with a small hole 482a at a position corresponding to the medal count clear switch 443a so that the medal count clear switch 443a can be pressed from outside the medal count control board case 482. More specifically, a recess 482b is formed at a position corresponding to the medal count clear switch 443a in the medal count control board case 482, and a small hole 482a is formed in approximately the center of the recess 482b.

The medal count clear switch 443a is a switch that is not used under normal circumstances, and is provided for use when an unexpected state occurs in the medal count control (control related to payout, etc.) related to the management of the number of accumulated game media (number of credits). Therefore, in order to prevent easy operation by human hands, the size of the small hole 482a provided in the medal count control board case 482 is set to a size that a human finger cannot enter. Specifically, the size of the small hole 482a is set to a diameter of, for example, approximately 2 mm or less, and is set to a size that cannot be pressed without using some kind of tool. Then, when an attendant of the game store presses the medal count clear switch 443a from outside the medal count control board case 482, he or she inserts a dedicated tool for pressing into the small hole 482a and presses the medal count clear switch 443a with the dedicated tool. By configuring the pressing mode in this way, it is possible to prevent the medal count clear switch 443a from being pressed by mistake.

In this embodiment, the main control board 441 and the medal count control board 443 are stored in separate control board cases, but the present invention is not limited to this. For example, the main control board 441 and the medal count control board 443 may be configured as a single control board. In this case, the main control microprocessor 450 described later, the medal count control microprocessor 460 described later, and the medal count clear switch 443a described later are mounted on the same control board. In this case, the control board case 483 that stores the control board on which the main control microprocessor 450 described later, the medal count control microprocessor 460 described later, and the medal count clear switch 443a described later are mounted is also one (see FIG. 40C). In addition, as shown in FIG. 40C, the control board case 483 has a recess 483b formed at a position corresponding to the location of the medal count clear switch 443a, and a small hole 483a is formed in the approximate center of the recess 483b to enable the medal count clear switch 443a to be pressed from outside the control board case 483.

For example, the main control board 441 and the medal count control board 443 may each be stored as separate boards in the control board case 483 shown in FIG. 40C. In this case, the main control board 441 and the medal count control board 443 are connected BtoB (Board to Board) in the control board case 483.

The sub-control circuit board 442 is equipped with a sub-control circuit (sub-control means) (not shown). The sub-control circuit is electrically connected to a main control microprocessor 450 (main control circuit) (described below) in the main control board 441 via the sub-relay board 446 and the door relay board 444, and performs processes such as deciding and executing the performance content based on commands sent from the main control microprocessor 450. The sub-control circuit is basically composed of a sub-CPU (performance control means), sub-RAM, rendering processor, drawing RAM, LED driver, sound IC, backup memory (FRAM (registered trademark)), etc.

The sub-relay board 446 is disposed within the cabinet 411a and is a relay board on which wiring is mounted to connect the sub-control board 442 to boards disposed around the sub-control board 442 and various device sections (units).

The operation switch 424S detects that the operation button 424 has been pressed by the player, and outputs the detection signal to the sub-control board 442 via the sub-relay board 446. The effect switch 425S detects that the effect button 425 has been pressed by the player, and outputs the detection signal to the sub-control board 442 via the sub-relay board 446.

The LED drive board 434 is a board on which drive circuits for the various lamps that make up the LED group 435 are mounted. The LED group 435 is composed of, for example, the lamp 428 provided on the front door 411b, the 7-segment display 415a, the bed lamp 415b, and a light source (not shown) that emits light to illuminate the decorative panel from the back side.

The speaker group 429 includes speakers 429L and 429R as well as various other speakers not shown. The display device 413 is a display device that is primarily used to perform effects by displaying images, and is, for example, a liquid crystal display device or a display device that performs effects (notifications) using dot patterns represented by turning on and off multiple LEDs.

[10-4-3. Configuration of main control board]
Next, the internal configuration of the main control board 441 will be described with reference to Fig. 41. Fig. 41 is a block diagram showing an example of the internal configuration of the main control board 441 of the pachinko slot machine 401.

The main control board 441 includes a main control microprocessor 450 (game control means), a clock pulse generating circuit 451, a power management circuit 452, a multifunction LSI (Large Scale Integrated Circuit) 453, and a role ratio monitor 454 (ratio display). The configurations of the main control microprocessor 450 and the role ratio monitor 454 will be described in detail later.

The clock pulse generating circuit 451 generates a clock pulse signal for operating the main CPU and outputs the generated clock pulse signal to the main control microprocessor 450. The main control microprocessor 450 executes a control program based on the input clock pulse signal.

The power management circuit 452 manages fluctuations in the 12V DC power supply voltage supplied from the power supply board 430b (see FIG. 39) and supplies 5V DC (VCC) power to the main control microprocessor 450. When the power is turned on (when the power supply voltage exceeds the startup voltage value (10V) from 0V), the power management circuit 452 outputs a reset signal to a reset controller 506 (XSRST) in the main control microprocessor 450 (described later), and when a power interruption occurs (when the power supply voltage falls from 12V to below the power interruption voltage value (10.5V)), the power management circuit 452 outputs a power interruption detection signal to a parallel input port 511 (XINT) in the main control microprocessor 450 (described later). That is, the power management circuit 452 also functions as a means (startup means) for outputting a reset signal (startup signal) to the main control microprocessor 450 when power is turned on, and as a means (power failure means) for outputting a power failure detection signal (power failure signal) to the main control microprocessor 450 when a power failure occurs.

The multifunction LSI 453 is connected to an external bus interface 504 in the main control microprocessor 450, which will be described later. The multifunction LSI 453 is also connected to the multifunction LSI 444a in the door relay board 444 (see Figures 88 and 89) via a serial bus so as to be able to communicate serially, and the detection signals of the switches connected to the door relay board 444 are sent to the multifunction LSI 453 by serial communication. The multifunction LSI 453 is also connected to the buffer IC 463 in the medal count control board 443, and inputs and outputs various signals to and from the buffer IC 463. In the communication control between the multifunction LSI 453 in the main control board 441 and the multifunction LSI 444a in the door relay board 444, the multifunction LSI 453 in the main control board 441 operates as a master IC, and the multifunction LSI 444a in the door relay board 444 operates as a slave IC (see Figures 88 and 89).

[10-4-4. Configuration of medal count control board]
Next, the internal configuration of the medal count control board 443 will be described with reference to Fig. 42. Fig. 42 is a block diagram showing an example of the internal configuration of the medal count control board 443 of the pachislot 401.

The medal count control board 443 is equipped with a medal count control microprocessor 460 (medal count control circuit, game value control means), a clock pulse generating circuit 461, and a power supply management circuit 462. In the pachislot 401 of this embodiment, the medal count control microprocessor 460 is configured with the same microprocessor as the main control microprocessor 450 provided in the main control board 441. The configuration of the medal count control microprocessor 460 will be described in detail later.

As is clear from a comparison between FIG. 42 and FIG. 41, the configuration of the medal count control board 443 is a configuration in which the multi-function LSI 453 and the role ratio monitor 454 are omitted from the main control board 441. In addition, the configurations and functions of the clock pulse generating circuit 461 and the power supply management circuit 462 provided on the medal count control board 443 are similar to the configurations and functions of the clock pulse generating circuit 451 and the power supply management circuit 452 provided on the main control board 441, respectively. Therefore, a description of the configurations and functions of the clock pulse generating circuit 461 and the power supply management circuit 462 will be omitted here.

[10-4-5. Configuration of main control and medal count control microprocessors]
Next, the internal configuration of the main control microprocessor 450 and the medal count control microprocessor 460 will be described with reference to Fig. 43. Fig. 43 is a block diagram showing the internal configuration of the main control microprocessor 450 and the medal count control microprocessor 460.

The main control microprocessor 450 and the medal count control microprocessor 460 are both microprocessors with security functions for gaming machines. As described above, in this embodiment, the main control microprocessor 450 has the same configuration as the medal count control microprocessor 460, and so here the main control microprocessor 450 and the medal count control microprocessor 460 are simply referred to as "microprocessor MP" for explanation. Note that for components with different functions between the main control microprocessor 450 and the medal count control microprocessor 460, the differences will be explained appropriately each time.

The microprocessor MP has a CPU 501, a ROM 502, a RAM 503, an external bus interface 504, a clock circuit 505, a reset controller 506, an arithmetic circuit 507, a matching block 508, unique information 509, a random number circuit 510 (random number generating circuit), a parallel input port 511, an interrupt controller 512, a timer circuit 513, a serial communication circuit 514, a parallel output port 515, and a signal bus 516 (local bus). The components of the microprocessor MP other than the signal bus 516 are connected to each other via the signal bus 516.

The CPU 501 executes various control programs and performs various controls based on the clock pulses generated by the clock circuit 505. In the main control microprocessor 450, the CPU 501 (hereinafter also referred to as the "main CPU") executes various control programs and performs control related to the overall gaming operation. On the other hand, in the medal count control microprocessor 460, the CPU 501 (hereinafter also referred to as the "medal count control CPU") executes various control programs and mainly performs control related to the counting operation of gaming media (gaming value) at the time of payout and settlement.

Here, we will explain reel stop control as an example of a control operation by the main CPU 501 of the main control microprocessor 450.

The main CPU 501 counts the number of times that pulses are output to the stepping motors of each reel 412L, 412C, 412L after detecting the reel index. In this way, the main CPU 501 manages the rotation angle of each reel (mainly, how many symbols the reel has rotated through). The reel index is information indicating that the reel has rotated once. This reel index is detected by a reel position detection unit (not shown) that includes, for example, an optical sensor with a light-emitting unit and a light-receiving unit, and a detection piece that is provided at a predetermined position on each reel and is interposed between the light-emitting unit and the light-receiving unit as each reel rotates.

Here, the management of the rotation angle of each reel 412L, 412C, 412L will be specifically described. The number of pulses output to the stepping motor is counted by a pulse counter provided in RAM 503 (hereinafter also referred to as "main RAM"). Then, each time the pulse counter counts the output of a predetermined number of pulses required for the rotation of one symbol, the symbol counter provided in main RAM 503 is incremented by one. A symbol counter is provided for each reel. The value of the symbol counter is cleared when the reel index is detected by the reel position detection unit (not shown). That is, in the pachislot 401 of this embodiment, the symbol counter is managed to manage how many symbols have rotated since the reel index was detected. Therefore, the position of each symbol on each reel is detected based on the position where the reel index is detected.

The ROM 502 stores various control programs executed by the CPU 501, various data tables, etc. The storage capacity of the ROM 502 is 12 kilobytes. In the main control microprocessor 450, the ROM 502 (hereinafter also referred to as the "main ROM") stores various control programs executed by the main CPU 501, various data tables, data for sending various control commands to the sub-control board 442, etc. On the other hand, in the medal count control microprocessor 460, the ROM 502 (hereinafter also referred to as the "medal count control ROM") stores various control programs executed by the medal count control CPU 501, various data required for input/output operations of signals and data between the main control board 441 and the game ball etc. connection terminal board 445 (game medium lending device 402, peripheral device 500).

The RAM 503 is provided with various storage areas in which various data (parameters, flags, etc.) used when the CPU 501 executes various control programs are stored. The RAM 503 has a storage capacity of 1 kilobyte. In the main control microprocessor 450, the RAM 503 (main RAM) is provided with a storage area in which various data such as internal lottery winning combinations determined by execution of the control programs are stored. On the other hand, in the medal count control microprocessor 460, the RAM 503 (hereinafter also referred to as the "medal count control RAM") is provided with a storage area in which various counters (e.g., medal counters and insertion counters, described below), various flags, etc. used when executing payout control, etc. are stored.

The external bus interface 504 is an interface circuit for electrically connecting the microprocessor MP to an external signal bus (not shown) to which various components provided outside the microprocessor MP are connected. In the main control microprocessor 450, the external bus interface 504 is an interface circuit for electrically connecting the main control microprocessor 450 to an external signal bus (not shown) to which components such as the reel unit 412 and the multifunction LSI 453 are connected. On the other hand, in the medal count control microprocessor 460, the external bus interface 504 is an interface circuit for electrically connecting the medal count control microprocessor 460 to an external signal bus (not shown) to which components such as the buffer IC 463 described below are connected.

The clock circuit 505 is configured to include, for example, a frequency divider (not shown) and converts the clock pulse signal for operating the CPU input from the clock pulse generating circuits 451 and 461 into a clock pulse signal of a frequency used by other components (for example, the timer circuit 513). The clock pulse signal generated by the clock circuit 505 is also output to the reset controller 506.

The reset controller 506 resets the IAT (Illegal Address Trap) and the WDT (watchdog timer) based on the reset signals input from the power management circuits 452 and 462. The arithmetic circuit 507 includes a multiplication circuit and a division circuit.

Unique information 509 stores unique information (identification information) of the microprocessor MP. The chip individual number of the microprocessor MP is composed of 4 bytes of data, and is set when the chip is manufactured. In addition, the chip individual number of the microprocessor MP is set to a different number for each chip.

In the main control microprocessor 450, the unique information (identification information) of the main control microprocessor 450 is stored in unique information 509. The ROM code of the main ROM 502 and the individual chip number of the main control microprocessor 450 are also stored in unique information 509. The ROM code of the main ROM 502 is composed of 4 bytes x 4 pieces of data, that is, 16 bytes of data. Each of the 4 bytes of data that make up the ROM code of the main ROM 502 is generated from data stored in the area of addresses "0000h" to "2FBFh" of the built-in ROM (main ROM 502), and the method of generating the 4 bytes of data also differs for each 4 bytes of data.

Meanwhile, in the medal count control microprocessor 460, the medal count control microprocessor 460's unique information (identification information) is stored in the unique information 509. In addition, the ROM code of the medal count control ROM 502 and the individual chip number of the medal count control microprocessor 460 are stored in the unique information 509. The ROM code of the medal count control ROM 502 is composed of 4 bytes x 4 pieces of data, that is, 16 bytes of data. Each of the 4 bytes of data that make up the ROM code of the medal count control ROM 502 is generated from data stored in the area of addresses "0000h" to "0FBFh" of the built-in ROM (medal count control ROM 502), and the method of generating the 4 bytes of data also differs for each 4 bytes of data.

The random number circuit 510 generates random numbers in a predetermined range (for example, 0 to 65535 or 0 to 255). The random number circuit 510 is composed of multiple random number registers, and can be composed of, for example, random number register 0 for obtaining 2-byte hard-latch random numbers, random number registers 1 to 3 for obtaining 2-byte soft-latch random numbers, and random number registers 4 to 7 for obtaining 1-byte soft-latch random numbers. In the main control microprocessor 450, the main CPU 501 extracts one value from the random numbers in the predetermined range generated by the random number circuit 510 as, for example, a random number value for an internal lottery.

The parallel input port 511 is an input port (memory map I/O) for signals input to the microprocessor MP from various circuits (e.g., power management circuits 452, 462, etc.) provided outside the microprocessor MP. The parallel input port 511 is also connected to the random number circuit 510 and the interrupt controller 512. In the main control microprocessor 450, the start switch 422S is connected to the parallel input port 511, and when the start switch 422S is turned on (on edge), a latch signal is output from the parallel input port 511 to a predetermined random number register (e.g., random number register 0) of the random number circuit 510. In the random number circuit 510, the predetermined random number register is latched by the input of the latch signal, and a 2-byte hard latch random number is obtained.

The interrupt controller 512 controls the timing of execution of interrupt processing by the CPU 501 based on a power interruption detection signal input from the power management circuits 452, 462 via the parallel input port 511, or a timeout signal input at a predetermined interval from the timer circuit 513. When a power interruption detection signal is input from the power management circuits 452, 462, or when a timeout signal is input from the timer circuit 513, the interrupt controller 512 outputs an interrupt request signal indicating an interrupt processing start command to the CPU 501. Then, the CPU 501 performs various interrupt processing based on the interrupt request signal input from the interrupt controller 512 in response to the timeout signal from the timer circuit 513.

Specifically, in the main control microprocessor 450, the interrupt controller 512 controls the timing of interrupt processing by the main CPU 501 based on a power interruption detection signal input from the power supply management circuit 452 via the parallel input port 511, or a timeout signal input from the timer circuit 513 at a cycle of 1.1172 msec. Then, the main CPU 501 performs various interrupt processing such as port input processing, reel control processing, data transmission processing to the sub-control board 442, data transmission processing to the medal count control board 443, 7-segment LED drive processing, and timer update processing based on an interrupt request signal input from the interrupt controller 512 in response to the timeout signal from the timer circuit 513 (see FIG. 65 described below).

On the other hand, in the medal count control microprocessor 460, the interrupt controller 512 controls the execution timing of the interrupt process by the medal count control CPU 501 based on the power interruption detection signal input from the power management circuit 462 via the parallel input port 511, or the timeout signal input from the timer circuit 513 at 1 msec intervals. Then, based on the interrupt request signal input from the interrupt controller 512 in response to the timeout signal from the timer circuit 513, the medal count control CPU 501 performs various interrupt processes such as port input process, game information reception process, data transmission process to the main control board 441, data transmission process to peripheral devices, data reception process from peripheral devices, and port output process (see FIG. 79 described below).

The timer circuit 513 (PTC) operates (counts the elapsed time) with the clock pulse signal (a clock pulse signal with a frequency obtained by dividing the clock pulse signal for operating the CPU by a frequency divider (not shown)) generated by the clock circuit 505. The timer circuit 513 outputs a timeout signal (trigger signal) to the interrupt controller 512 at a predetermined period (a period of 1.1172 msec for the main control microprocessor 450, and a period of 1 msec for the medal count control microprocessor 460).

The serial communication circuit 514 is a communication circuit that controls the serial communication of various data between the control board on which the communication circuit is implemented and various boards provided outside the control board. Specifically, in the main control microprocessor 450, the serial communication circuit 514 is a communication circuit that controls the serial communication of data (various control commands, various data, etc.) between the main control board 441 and various boards (e.g., the sub-control board 442, the medal count control board 443) provided outside the main control board 441. On the other hand, in the medal count control microprocessor 460, the serial communication circuit 514 is a communication circuit that controls the serial communication of data (various control signals, various data, etc.) between the medal count control board 443 and the main control board 441.

The serial communication circuit 514 is made up of four communication circuits SCU0 to SCU3, with only communication circuit SCU0 being made up of a bidirectional serial communication circuit, and communication circuits SCU1 to SCU3 being made up of serial communication circuits dedicated to transmission. In this embodiment, bidirectional serial communication is performed between the main control board 441 (main control microprocessor 450) and the medal count control board 443 (medal count control microprocessor 460) as described below, so communication circuit SCU0 is used on each control board.

The parallel output port 515 is an output port (memory map I/O) for signals output from the microprocessor MP to various circuits provided externally. In the pachislot 401 of this embodiment, data is sent and received between the main control board 441 and the medal count control board 443 using a FIFO (First In First Out) method.

[10-4-6. Configuration of the role ratio monitor]
Next, the configuration of the role ratio monitor 454 (ratio display) will be described with reference to Figures 44A and 44B. Note that Figure 44A shows an example of the installation of the role ratio monitor 454, and Figure 44B shows the contents of the information displayed on the role ratio monitor 454.

As shown in FIG. 44A, the role ratio monitor 454 is composed of a four-digit seven-segment LED, with the top two digits indicating the type of display content (ratio) and the bottom two digits indicating the ratio value (%) of the display content. The role ratio monitor 454 is installed inside the pachislot 401 because it is used when an administrator (such as an arcade staff member) checks whether the pachislot 401 has been tampered with. At this time, in order to prevent tampering with the role ratio monitor 454 itself, it is preferable that the role ratio monitor 454 be installed inside the main control board case that covers the main control board 441.

As a specific example of installation, for example, as shown in FIG. 44 (A-1), the role ratio monitor 454 may be mounted on the main control board 441, and this installation form is adopted in the pachislot 401. As a specific example of installation, for example, as shown in FIG. 44 (A-2), the role ratio monitor 454 may be mounted on another board (ratio display board) connected to the main control board 441, or as shown in FIG. 44 (A-3), the role ratio monitor 454 may be attached by connecting a 7-segment LED unit as the role ratio monitor 454 to the main control board 441. In either of these two installation forms, it is preferable to provide the role ratio monitor 454 inside the main control board case together with the main control board 441, as in the example shown in FIG. 44 (A-1).

Usually, a recording paper or a seal is attached to the main control board case, but when the role ratio monitor 454 is provided inside the main control board case, it is preferable to attach a seal so that the visibility of the role ratio monitor 454 is not impaired by the seal. The seal is intended to leave a trace that the main control board case has been opened, and is a specially processed seal that leaves a trace when removed. The recording paper is a sheet of paper for recording the installation, removal, or opening of the main control board case when it is performed according to the proper procedure. The identification number of the main control board 441 is printed on this recording paper, and furthermore, there is a space for writing the date and time of installation, removal, or opening, and the person in charge at that time. The "proper procedure" referred to here includes the manufacture of the gaming machine (when it is installed and fixed) and on-site inspection after installation in the gaming facility.

Next, a display example of the role ratio monitor 454 will be described. As shown in FIG. 44B, the role ratio monitor 454 displays the cumulative specific section ratio, the consecutive role ratio and role ratio for the last 6000 games, and the cumulative consecutive role ratio and role ratio. When the cumulative specific section ratio is displayed on the role ratio monitor 454, the upper two digits of the four-digit seven-segment LED display "AU", when the consecutive role ratio for the last 6000 games is displayed, the upper two digits display "=r", when the role ratio for the last 6000 games is displayed, the upper two digits display "=b", when the cumulative consecutive role ratio is displayed, the upper two digits display "Ar", and when the cumulative role ratio is displayed, the upper two digits display "Ab". In addition, the lower two digits of the four-digit seven-segment LED display the corresponding ratio in percentage.

Here, "specific section ratio" refers to the ratio of the number of plays in a game state that is advantageous to the player to the number of plays in all game states (i.e., the total number of plays). In this case, a game state that is advantageous to the player may include not only a notification state that notifies the player of information that is advantageous to the player (so-called during AT or ART), but also a chance zone (CZ) where there is a high expectation of transitioning to this notification state. Also, a bonus state that starts during a notification state may also be included in the advantageous game state in this case.

The main control board 441 counts the total number of plays, which indicates the number of plays in all game states, and the specific number of plays, which indicates the number of plays in a game state that is advantageous to the player, in a specified counter (not shown) provided in the main RAM 503, and calculates the specific section ratio using the formula shown below.
Specific section ratio = specific game count / total game count x 100

In addition, the "continuous feature ratio" refers to the ratio of the total number of game media paid out in a game state in which a first-class special feature or a feature continuous operation device related to a first-class special feature is in operation to the total number of game media paid out in all game states (i.e., the total number of payouts).

The main control board 441 counts, in a specific counter (not shown) provided in the main RAM 503, the total payout number indicating the total number of game media paid out in all game states and the first specific game payout number indicating the total number of game media paid out during operation of a first type special feature or a feature continuous operation device related to a first type special feature, and calculates the continuous feature ratio using the formula shown below.
Sequential bonus ratio = number of payouts during the first specific game / total number of payouts x 100

In addition, "role ratio" refers to the ratio of the total number of game media paid out while any of the game devices is in operation to the total number of game media paid out in all game states (i.e., the total number of payouts). Note that "any of the game devices" refers to a first type special game device, a game device continuous operation device related to a first type special game device, a second type special game device, a game device continuous operation device related to a second type special game device, or a normal game device. In addition, the so-called ART state and chance zone state are also advantageous states for the player, so these states may also be included in the state in which "any of the game devices" is in operation.

The main control board 441 counts the total payout number, which indicates the total number of game media paid out in all game states, and the second specific game payout number, which indicates the total number of game media paid out while any of the reels are in operation, in a specified counter (not shown) provided in the main RAM 503, and calculates the reel ratio using the formula shown below.
Sequential bonus ratio = number of payouts during the second specific game / total number of payouts x 100

In addition, "cumulative" refers to the entire period from when the pachislot 401 was installed to the present, and "for the last 6000 games" refers to the period from when 6000 games were played to the present. When calculating the percentage of the "cumulative," the main control board 441 need only calculate the percentage using the counting results that have been counted over the entire period, and when calculating the percentage of the "for the last 6000 games," the main control board 441 need only calculate the percentage using the counting results that have been counted over the period from when 6000 games were played to the present.

The various counters provided in the main RAM 503 are provided in an area that is not cleared (initialized) even when the power is turned on/off or settings are changed. In other words, the data related to the role ratio monitor 454 stored in the main RAM 503 is configured not to be erased (cleared) even when the power is turned on/off or settings are changed. The various counters provided in the main RAM 503 count data related to the role ratio monitor 454, with 400 games counted as one set. For example, when calculating the ratio over 6,000 games, the cumulative counting results of 15 sets are used to calculate the ratio.

The role ratio monitor 454 also switches between and displays various ratios calculated by the main control board 441. The method of switching the content displayed on the role ratio monitor 454 is arbitrary, and for example, the display of various ratios may be switched automatically at a predetermined interval, the display of various ratios may be switched manually in response to the operation of a dedicated switch, or the display of various ratios may be switched by combining automatic switching and manual switching.

However, when the example of attaching the role ratio monitor 454 shown in FIG. 44A is adopted in a slot machine that does not have an existing role ratio monitor 454, it is necessary to make major modifications to the existing slot machine. Therefore, when incorporating the configuration of the role ratio monitor 454 into an existing slot machine, a display provided in the existing slot machine may be used as the role ratio monitor 454 for displaying various ratios (or may serve as both). For example, since an existing slot machine is provided with a display that displays the number of game media stored (number of credits) and the number of game media paid out in the current game (number of payouts), this display may be used as the role ratio monitor 454.

In this case, for example, when a special operation is performed on the slot machine, the display of the display may be switched so that the type of display content (ratio) is displayed on the credit number display (credit lamp: not shown) and the percentage value of the display content is displayed on the payout number display (payout number lamp: not shown). The special operation performed at this time is arbitrary, but it is preferable that it is an operation using a switch provided inside the slot machine. This makes it possible to prevent the player from accidentally performing a special operation.

[10-5. Data communication mechanism and input/output mechanism between the main control board and the medal count control board]
Next, with reference to Fig. 45, the data communication mechanism and input/output mechanism between the main control board 441 and the medal count control board 443 in the slot machine 401 of this embodiment will be described. Also, with reference to Fig. 45, the method of controlling the turning on/off of the MAX BET button 416 in the slot machine 401 will be described. Fig. 45 is a diagram showing the schematic configuration of the data communication mechanism and input/output mechanism between the main control board 441 and the medal count control board 443, and the outline of the control method of turning on/off the MAX BET button 416. Note that, in Fig. 45, in order to simplify the explanation, only the components necessary for the data communication operation and input/output operation between the main control board 441 and the medal count control board 443 are shown.

As shown in FIG. 45, the data communication mechanism between the main control board 441 and the medal count control board 443 is configured by connecting the receiving port RX0 of the serial communication circuit 514 (SCU0) of the main control board 441 and the transmitting port TX0 of the serial communication circuit 514 (SCU0) of the medal count control board 443 with a signal line for serial communication, and connecting the transmitting port TX0 of the serial communication circuit 514 (SCU0) of the main control board 441 and the receiving port RX0 of the serial communication circuit 514 (SCU0) of the medal count control board 443 with a signal line for serial communication (so-called cross connection). Then, data communication is performed between the main control board 441 and the medal count control board 443 using a half-duplex serial communication method. Note that in the half-duplex serial communication performed between the main control board 441 and the medal count control board 443, the main control board 441 is the master and the medal count control board 443 is the slave.

In addition, in this embodiment, a data input/output mechanism (hereinafter referred to as a "game medium status function") is provided between the main control board 441 and the medal count control board 443, in addition to the above-mentioned data communication mechanism (serial line), which outputs information (hereinafter referred to as the "game medium status") corresponding to the number of game media that can be inserted (reserved number) from the medal count control board 443 to the main control board 441. In the pachislot 401, all management of the game medium number is performed by the medal count control board 443, so a medal counter (storage area, reserved number counting means) for counting the reserved number of game media (number that can be inserted, number of credits) is provided in the medal count control RAM 503 of the medal count control board 443. Then, in the game medium status function, information regarding the value of this medal counter is output from the medal count control board 443 to the main control board 441 as the game medium status.

The game medium status function is configured using two ports that can be set to input or output data with GPIO (General Purpose Input/Output). Specifically, as shown in FIG. 45, the game medium status function is configured by connecting the first input port PI0 of the main control board 441 and the first output port PO0 of the medal count control board 443 with a first signal line, and connecting the second input port PI1 of the main control board 441 and the second output port PO1 of the medal count control board 443 with a second signal line. In this embodiment, the GPIO is configured by input ports and output ports provided on the multi-function LSI 453 of the main control board 441 and the buffer IC 463 of the medal count control board 443, respectively, and is illustrated in a simplified form in FIG. 45. GPIO means a general-purpose port that can be set as an input port or an output port.

The game medium status function forms two bits of data using the value of the first control signal ("0" or "1") input from the first output port PO0 of the medal count control board 443 to the first input port PI0 of the main control board 441, and the value of the second control signal ("0" or "1") input from the second output port PO1 of the medal count control board 443 to the second input port PI1 of the main control board 441, and the game medium status is represented by the two bits of data. Note that in this embodiment, of the two bits of data representing the game medium status, the value of bit 0 is the value of the first control signal, and the value of bit 1 is the value of the second control signal.

For example, if the medal counter value is "0", the game medium status function inputs a first control signal "0" to the first input port PI0 of the main control board 441, and a second control signal "0" to the second input port PI1. As a result, the main control board 441 detects "00B" as the game medium status, and can determine that the number of game media that can be inserted is "0" based on the detection result. Also, for example, if the medal counter value is "1", the game medium status function inputs a first control signal "1" to the first input port PI0 of the main control board 441, and a second control signal "0" to the second input port PI1. As a result, the main control board 441 detects "01B" as the game medium status, and can determine that the number of game media that can be inserted is "1" based on the detection result.

For example, if the medal counter value is "2", the game medium status function inputs a first control signal "0" to the first input port PI0 of the main control board 441, and a second control signal "1" to the second input port PI1. As a result, the main control board 441 detects the game medium status as "10B", and can determine that the number of game media that can be inserted is "2" based on the detection result. Furthermore, for example, if the medal counter value is "3" or more, the game medium status function inputs a first control signal "1" to the first input port PI0 of the main control board 441, and a second control signal "1" to the second input port PI1. As a result, the main control board 441 detects the game medium status as "11B", and can determine that the number of game media that can be inserted is "3" or more based on the detection result.

In this way, in this embodiment, the main control board 441 can determine the number of game media that can be inserted (the value of the medal counter) managed by the medal count control board 443 based on the game medium status (2-bit information) obtained by the game medium status function. As a result, the main control board 441 can determine, from the minimum information obtained from this game medium status function, whether the number of game media that can be inserted is equal to or greater than the maximum specified number for the number of inserts ("3" in this embodiment).

In addition, in the pachislot 401 of this embodiment, the game medium status (2-bit information) acquired by the main control board 441 through the game medium status function described above is used to control (control the light emission pattern) the turning on/off of the bet button LED (not shown) provided inside the MAX BET button 416 (hereinafter, abbreviated to "turning on/off the MAX BET button 416"). This control operation will be specifically described with reference to FIG. 45.

First, when the main control board 441 acquires the gaming medium status by the above-mentioned gaming medium status function, the gaming medium status is stored in an input port storage area (not shown) provided in the main RAM 503. Next, when a no-operation command (which is also called a periodic command or a periodic command because it is transmitted at a fixed period) is transmitted from the main control board 441 to the sub-control board 442, the no-operation command includes (adds) the gaming medium status and transmits it. Then, on the sub-control board 442 side, the MAX BET button 416 is controlled to be turned on or off based on the gaming medium status contained in the no-operation command. At this time, if the gaming medium status contained in the no-operation command is "11B" (the number of gaming media that can be inserted is "3" or more), the MAX BET button 416 is controlled to be turned on, and otherwise the MAX BET button 416 is controlled to be turned off.

In this embodiment, the turning on/off of the MAX BET button 416 is controlled by the sub-control board 442, but the turning on/off of the MAX BET button 416 may also be controlled by the main control board 441. In this case, too, the turning on/off of the MAX BET button 416 can be controlled based on the gaming medium state input from the medal count control board 443 to the main control board 441 by the gaming medium state function described above.

When the above-mentioned game medium status function is provided, the main control board 441 can determine whether the number of game media that can be inserted is equal to or greater than the maximum number of game media that can be inserted, that is, whether a game can be started, based on the minimum information (game medium status) input from the medal count control board 443 to the main control board 441. Also, when the above-mentioned game medium status function is provided, the main control board 441 can determine the pressing conditions of the MAX BET button 416 based on the minimum information (game medium status) input from the medal count control board 443 to the main control board 441, and the sub-control board 442 can determine the lighting conditions of the MAX BET button 416 (bet button LED). Furthermore, when the above-mentioned game medium status function is provided, it becomes possible to introduce and operate a medalless game machine with just a simple modification of the program.

[10-6. Bet number setting operation and line LED on/off operation when 1 bet button is pressed]
Next, the operation of setting the number of game media inserted (number of bets) when the 1 bet button 417 is pressed in the pachislot 401 of this embodiment and the operation of turning on/off the line LED for displaying the number of bets will be described. Note that in this embodiment, all management of the number of game media is performed by the medal count control board 443, so a medal counter (storage area) for counting the number of game media bets (number of inserted) is provided in the medal count control RAM 503 of the medal count control board 443.

In this embodiment, each time the 1 BET button 417 is pressed, a medal insertion request command (1 BET insertion command) is sent from the main control board 441 to the medal count control board 443. When the MAX BET button 416 is pressed, a medal insertion request command (1 BET insertion command) is sent from the main control board 441 to the medal count control board 443 up to three times with one pressing operation (see FIG. 60 described below).

In the medal count control board 443, the number of times a medal insertion request command (1 BET insertion command) is received is counted by an insertion counter, thereby managing the number of gaming media inserted (number of bets). Then, in the medal count control board 443, the counting result of the insertion counter is added to a response command (Ack command) to the medal insertion request command, and the response command is sent to the main control board 441.

The main control board 441 controls the turning on/off (light emission pattern) of the "1 BET", "2 BET", and "3 BET" line LEDs (see FIG. 37A) provided on the game information display unit 426a based on the counting result (number of coins inserted) of the insertion counter added to the received response command.

In the above-mentioned operation of setting the number of bets when the 1 bet button is pressed and the operation of turning on/off the line LEDs, if the 1 bet button 417 is pressed four times in succession, the process of updating the value of the insertion counter in the medal count control board 443 updates the value of the insertion counter from "3" to "1". In other words, the number of bets is updated from "3" to "1". Therefore, if the 1 bet button 417 is pressed four times in succession, the count result (number of bets) of the insertion counter added to the response command (Ack command) sent (returned) from the medal count control board 443 to the main control board 441 will be "1". At this time, the value of the insertion counter (number of bets) is subtracted by 2, and the value of the medal counter (number of reserved medals) is added by 2.

Then, on the main control board 441 side that has received the response command (Ack command), based on the acquired count result of the insertion counter of "1", only the "1 BET" line LED is controlled to light up. In other words, when the 1 BET button 417 is pressed four times in succession, the lighting state of the line LEDs on the game information display unit 426a changes from a state in which all the line LEDs of "1 BET", "2 BET", and "3 BET" were lit up to a state in which only the "1 BET" line LED is lit up.

Now, with reference to Figure 46, the lighting control of the line LEDs for displaying the number of bets when the 1 bet button is pressed will be described in more detail. Figure 46 is a timing chart of the lighting/extinguishing control of the line LEDs for displaying the number of bets when the 1 bet button is pressed. Note that in the example shown in Figure 46, the value of the insertion counter (number of insertions, number of bets) before the first 1 bet operation (initial state) is "0", and the value of the medal counter (number of medals stored) is "50".

First, when the main control board 441 detects the first pressing of the 1 BET button 417 (T1), a medal insertion request command (1 BET insertion command) with the maximum specified number of gaming media ("3") added is sent from the main control board 441 to the medal count control board 443 (T2).

Next, when the first medal insertion request command is received by the medal count control board 443, the medal count control board 443 adds 1 to the insertion counter value (number of insertions) and subtracts 1 from the medal counter value. As a result, the insertion counter value becomes "1" and the medal counter value becomes "49". At this time, an Ack command (acknowledgement response command) with the insertion counter value (counting result) "1" added is sent from the medal count control board 443 to the main control board 441 (T3).

Next, when the main control board 441 receives an Ack command with the value (counting result) of the input counter of "1" added, the main control board 441 controls the lighting of the "1 BET" line LED based on the value (counting result) of the input counter of "1" (T4).

Next, when the main control board 441 detects a second press of the 1 BET button 417 (T5), a medal insertion request command (1 BET insertion command) with the maximum specified number of gaming media ("3") added is sent from the main control board 441 to the medal count control board 443 (T6).

Next, when the medal count control board 443 receives the second medal insertion request command, the medal count control board 443 increments the insertion counter value by 1 and decrements the medal counter value by 1. As a result, the insertion counter value (number of insertions) becomes "2" and the medal counter value becomes "48". At this time, an Ack command with the insertion counter value (counting result) "2" added is sent from the medal count control board 443 to the main control board 441 (T7).

Next, when the main control board 441 receives an Ack command with the value (counting result) of the insertion counter of "2" added, the main control board 441 controls the lighting of the "1 BET" and "2 BET" line LEDs based on the value (counting result) of the insertion counter of "2" (T8).

Next, when the main control board 441 detects a third press of the 1 BET button 417 (T9), a medal insertion request command (1 BET insertion command) with the maximum specified number of gaming media ("3") added is sent from the main control board 441 to the medal count control board 443 (T10).

Next, when the medal count control board 443 receives the third medal insertion request command, the insertion counter value is incremented by 1 and the medal counter value is decremented by 1. As a result, on the medal count control board 443 side, the insertion counter value (number of insertions) becomes "3" and the medal counter value becomes "47". At this time, an Ack command with the insertion counter value (counting result) "3" added is sent from the medal count control board 443 to the main control board 441 (T11).

Next, when the main control board 441 receives an Ack command with the value (counting result) of the input counter of "3" added, the main control board 441 controls the lighting of the "1 BET", "2 BET", and "3 BET" line LEDs, as well as the "START" line LED, based on the value (counting result) of the input counter of "3" (T12).

Next, when the main control board 441 detects a fourth press of the 1 bet button 417 (T13), a medal insertion request command (1 BET insertion command) with the maximum specified number of gaming media ("3") added is sent from the main control board 441 to the medal count control board 443 (T14).

Next, when the medal count control board 443 receives the fourth medal insertion request command, the medal count control board 443 sets the insertion counter value to "1" (subtracts 2) and adds 2 to the medal counter value. As a result, the insertion counter value (number of insertions) becomes "1" and the medal counter value becomes "49". At this time, an Ack command with the insertion counter value (counting result) "1" added is sent from the medal count control board 443 to the main control board 441 (T15).

Next, when the main control board 441 receives an Ack command with the insertion counter value (counting result) of "1" added, the main control board 441 controls the lighting of the "1 BET" line LED and controls the turning off of the "2 BET", "3 BET" and "START" line LEDs based on the insertion counter value (counting result) of "1" (T16).

After that, if the main control board 441 detects a fifth or subsequent press of the 1 bet button 417, the above operations from operation T5 onwards are repeated.

The specific content of the process for setting the number of bets when the 1 bet button is pressed will be described later in detail using Figure 74 (a flowchart of the process performed by the medal count control board 443 when a medal insertion request command is received).

When the above-mentioned function of setting the number of bets when the 1 bet button is pressed and turning on/off the line LEDs (a function known as the "1 BET loop") is provided, the main control board 441 can determine the conditions for pressing the 1 bet button 417 and the conditions for turning on the line LEDs that display the number of bets based on the minimum information input from the medal count control board 443 to the main control board 441 (the value of the insertion counter (counting result) added to the Ack command). Also, when the above-mentioned function of setting the number of bets and turning on/off the line LEDs is provided, it becomes possible to introduce and operate a medalless gaming machine with just a simple modification of the program.

In this embodiment, when the fourth pressing of the 1 bet button 417 is detected, the number of bets is set to "1", i.e., the value of the insertion counter (counting result) is returned from "3" to "1", but the present invention is not limited to this. For example, when the fourth pressing of the 1 bet button 417 is detected, the number of bets may be returned from "3" to "2". In this case, in operation T16, the "1 BET" and "2 BET" line LEDs are controlled to be turned on, and the "3 BET" and "START" line LEDs are controlled to be turned off, and then the operations from operation T9 onwards are repeated.

[10-7. Control when the start lever is operated during settlement of gaming media]
In the pachislot 401 of this embodiment, even during the settlement operation of the gaming medium (game value), the game is controlled so that the game can be started when the start lever 422 is pressed (when the game start operation is performed). The content of this game start control will be described with reference to FIG. 47. Note that FIG. 47 is a timing chart of the game start process that is performed when the start lever 422 is operated during the settlement of the gaming medium. Note that in the example shown in FIG. 47, the value of the insertion counter (the number of insertions) is "3" and the value of the medal counter (the number of medals stored) is "47" immediately before the settlement starts (initial state).

First, when the medal count control board 443 detects that the settlement button 418 has been pressed (T21), the medal counter value clearing process (settlement process) is initiated.

Next, when the main control board 441 detects the pressing of the start lever 422 during settlement of the gaming media (T22), a game start request command (start lever command) with the number of gaming media inserted ("3") added is sent from the main control board 441 to the medal count control board 443 (T23).

Next, when the medal count control board 443 receives the game start request command, an Ack command (acknowledge response command) is sent from the medal count control board 443 to the main control board 441 (T24). In the example shown in FIG. 47, the medal counter value ("47") has already been settled at the time the medal count control board 443 receives the game start request command. Therefore, the value of the insertion counter at the time of receiving the game start request command is "3" and the medal counter value is "0". Then, in the medal count control board 443, the insertion counter value is cleared (set to "0") when the Ack command is sent.

Then, when the main control board 441 receives an Ack command from the medal count control board 443, the game begins (T25).

The specific content of the game start processing during settlement described above will be described in detail later using Figure 62 (a flowchart of the game start processing performed by the main control board 441).

If the above-mentioned function to start playing during settlement is provided, even when settlement of gaming media is in progress, it is possible to play the number of gaming media inserted (number of bets), making it possible to end play without performing a return operation. In addition, if the above-mentioned function to start playing during settlement is provided, it becomes possible to introduce and operate a medal-less gaming machine with just a simple modification of the program.

Note that the control when the start lever 422 is pressed during settlement of gaming media is not limited to the above example, and the following control may also be performed.

For example, when the start lever 422 is pressed during settlement, the medal count control board 443 first returns a Nack command (non-acknowledge response command) to the main control board 441 as a response command in response to the game start request command (start lever command) with the number of game media inserted ("3") added, which is sent from the main control board 441 to the medal count control board 443. Next, the main control board 441 that received the Nack command moves to a standby state. Meanwhile, after sending the Nack command, the medal count control board 443 settles the amount of game media inserted and the amount of game media equivalent to the medal counter value (reserved number). At the end of this settlement, the game media state detected by the main control board 441 changes to "00B", so the main control board 441 can recognize the end of settlement from this change in game media state. Then, when the main control board 441 recognizes the completion of settlement based on the gaming media status, the main control board 441 cancels the pressing of the start lever 422, and the control state of the main control board 441 transitions to a state waiting for gaming media to be bet (inserted).

[10-8. Function to deal with when medal counter exceeds upper limit]
[10-8-1. What to do if a medal counter limit exceeding error occurs when deciding on a winning combination]
In the pachislot 401 of this embodiment, when a winning combination (a winning combination) is determined and a payout number of game media occurs as a result, the payout number is added to the value of the medal counter provided in the medal count control board 443. However, in this embodiment, the medal counter for counting the number of stored game media provided in the medal count control board 443 has a counting upper limit of "16369", so when the payout number is added to the medal counter value, the value after addition may exceed the upper limit. In such a situation where the medal counter's upper limit may be exceeded, the following measures are taken. The payout number of game media is added to the medal payout request command sent from the main control board 441 to the medal count control board 443 when the winning combination is determined.

First, when the medal count control board 443 receives a medal payout request command, it determines whether the medal counter value after the addition will exceed its upper limit (16369) when the payout number (subsequent data) attached to the command is added to the current medal counter value. Then, if this determination process determines that the medal counter value after the addition will exceed its upper limit (16369), the medal count control board 443 does not add to the payout number, and sends a Nack command (not acknowledged response command) with an upper limit exceeded error code attached to it to the main control board 441, and the control state of the medal count control board 443 transitions to a standby state.

On the other hand, when the main control board 441 receives a Nack command from the medal count control board 443, the main control board 441 displays an error code indicating that the medal counter value has exceeded the upper limit based on the upper limit exceeding error code on the two-digit seven-segment LED for payout display on the game information display unit 426a (when an error occurs, this becomes the so-called "error segment"), thereby suggesting to the player to perform a settlement operation. At this time, the main control board 441 also transmits an error command to the sub-control board 442. Then, on receiving the error command, the sub-control board 442 uses a presentation device such as the display device 413 to notify the player of the error so as to encourage the player to perform a settlement operation.

When the medal count control board 443 in standby detects a player's settlement operation, the game media is settled for the medal counter value, and the medal counter value is cleared. Meanwhile, the main control board 441 judges whether the settlement for the medal counter value has been completed based on the game media state input by the game media state function. Then, when the main control board 441 judges that the settlement for the game media for the medal counter value has been completed (when it detects that the game media state has changed to "00B"), the error is cleared, and the error display on the two-digit 7-segment LED for payout display (Figure 37C) is erased and the original display is restored. At this time, the medal payout request command, to which the number of game media to be paid out generated by the determination of the winning combination is added, is resent from the main control board 441 to the medal count control board 443.

When the medal count control board 443 receives the resent medal payout request command, the payout number added to the command is added to the medal counter value, and an Ack command (acknowledgement response command) is sent from the medal count control board 443 to the main control board 441.

Now, referring to Figure 48, we will specifically explain the control content when the medal counter exceeds the upper limit as described above. Figure 48 is a diagram showing a timing chart of various control operations that are performed when the medal counter exceeds the upper limit. Note that in the example shown in Figure 48, when the winning role is determined (initial situation), the value of the insertion counter (number of insertions) is set to "0", and the value of the medal counter (number of medals stored) is set to "16369" (upper limit).

In the example shown in FIG. 48, in the initial state, the medal counter value (reserved number) is "16369" (upper limit), so the main control board 441 detects "11B" as the gaming medium state (T31). Next, a medal payout request command with the payout number corresponding to the achieved role (15 medals in the example shown in FIG. 48) added as subsequent data is sent from the main control board 441 to the medal count control board 443 (T32).

Next, the medal count control board 443 determines whether or not the medal counter value after the addition of the payout number of the received gaming media to the current medal counter value will exceed its upper limit. In the example shown in FIG. 48, when the payout number of the received gaming media "15" is added to the current medal counter value "16369", the medal counter value after the addition exceeds its upper limit value ("16369"), so the payout number is not added to the medal counter value and a Nack command (non-acknowledge response command) is sent from the medal count control board 443 to the main control board 441 (T33). Then, the control state of the medal count control board 443 transitions to a standby state (awaiting settlement state) (T34).

On the other hand, the main control board 441, which has received the Nack command (non-acknowledge command), sends an error command to the sub-control board 442 indicating an upper limit exceeded error, and displays the upper limit exceeded error in an error segment (T35), suggesting that the player perform a settlement operation. At this time, the sub-control board 442, which has received the error command indicating an upper limit exceeded error, issues an error notification to encourage the player to perform a settlement operation. Thereafter, the control state of the main control board 441 transitions to a standby state (a state waiting for error release) until the player performs a settlement operation and the error is released (T36). In this standby state, the main control board 441 monitors the gaming medium state input from the medal count control board 443, and determines whether or not the gaming medium has been settled.

When the gaming media is settled, the gaming media status changes from "11B" to "00B", and when this change is detected by the main control board 441 (T37), the error is cleared in the main control board 441. Next, a medal payout request command with the payout number corresponding to the achieved role (15 medals in the example shown in FIG. 48) added as subsequent data is resent from the main control board 441 to the medal count control board 443 (T38).

Then, the medal count control board 443 determines whether the medal counter value after adding the re-received number of game media payouts to the current medal counter value will exceed its upper limit. In the example shown in FIG. 48, adding the received number of game media payouts "15" to the current (after settlement) medal counter value "0" does not exceed the medal counter's upper limit, so the payout number "15" is added to the medal counter value "0" and an Ack command (acknowledgement response command) is sent from the medal count control board 443 to the main control board 441 (T39). At this time, the main control board 441 detects that the game medium status has changed from "00B" to "11B" (T40).

The specific content of the above process that is performed when an error occurs in which the medal counter exceeds the upper limit when determining the winning combination will be described later in detail using Figure 64 (a flowchart of the medal payout process performed by the main control board 441) and Figure 76 (a flowchart of the process performed by the medal count control board 443 when a medal payout request command is received).

In addition, the method of dealing with the occurrence of a medal counter upper limit exceeding error when determining the winning combination is not limited to the above-mentioned example, and the following method may be used, for example.

First, the medal counter is configured so that it can count even if it exceeds its upper limit (16369). Then, if the medal counter value exceeds the upper limit (16369) when the number of payouts of the corresponding gaming media is added to the medal counter value when the winning combination is determined (for example, in the example shown in FIG. 48, the medal counter = 16384), the medal count control board 443 adds the payout number to the medal counter value and sends a Nack command with an upper limit exceeded error code to the main control board 441. In the main control board 441 and the sub-control board 442 that receive this Nack command, a notification (error notification) is issued in the same manner as described above that a medal counter upper limit exceeded error has occurred, and an error notification is issued to prompt the player to perform a settlement operation.

Next, when the settlement operation is performed, the medal count control board 443 settles the gaming media for the medal counter value to which the payout number has been added (for example, 16,384). During this settlement, the main control board 441 monitors the gaming media status input by the gaming media status function, and when the gaming media status changes from "11B" to "00B", it determines that settlement is complete and the error is cleared. In dealing with such a medal counter upper limit exceeding error, the medal counter upper limit value "16,369" serves as a threshold for whether or not to execute a process to report an error and prompt the settlement operation.

[10-8-2. Notification function for medal counter upper limit exceeding error and upper limit exceeding notice error when a winning combination is determined]
In the pachislot 401 of this embodiment, when a minor win is achieved (a win) and game media is paid out, if the number of game media paid out is added to the medal counter value (reserved number) and exceeds the medal counter's upper limit (16369: hereinafter also referred to as the "first upper limit"), that is, if a medal counter upper limit exceeding error occurs, game play becomes impossible and an error notification function (upper limit exceeding error notification function) is provided to prompt the player to settle the game media.

Specifically, when a medal counter upper limit exceeding error occurs, an error code (numbers, letters, etc.) corresponding to the medal counter upper limit exceeding error is displayed on a one-digit seven-segment LED for error display in the medal count display unit 426b (see FIG. 37B), whose display is controlled by the medal count control board 443. In this embodiment, when a medal counter upper limit exceeding error occurs, an error code (numbers, letters, etc.) corresponding to the medal counter upper limit exceeding error is also displayed on a two-digit seven-segment LED for payout display in the game information display unit 426a (see FIG. 37A), whose display is controlled by the main control board 441. Note that the manner in which an upper limit exceeding error is not limited to this example, and for example, an upper limit exceeding error may be notified only by a one-digit seven-segment LED for error display in the medal count display unit 426b (see FIG. 37B).

In addition, in the pachislot 401 of this embodiment, when a small win is achieved (a win) and game media is paid out, if the number of paid game media is added to the medal counter value (reserved number) and exceeds a predetermined value (hereinafter also referred to as the "second upper limit value") that is less than the upper limit value of the medal counter (16369) and is relatively close to the upper limit value, an error notification function (upper limit exceeded notice error notification function) is also provided, which notifies the player that the medal counter value is approaching the upper limit value and prompts the player to perform a game media settlement operation. Note that here, a situation in which the number of paid game media is added to the medal counter value and the sum exceeds the second upper limit value is referred to as an "upper limit exceeded notice error". In addition, in this embodiment, the second upper limit value of the medal counter value is set, for example, to "15000" or "16369 - maximum payout number (depending on the model, there are 6, 9, 11, 15, etc.)".

In the upper limit exceeded warning error notification function, when an upper limit exceeded warning error occurs in the medal counter, an error code (numbers, letters, etc.) corresponding to the medal counter upper limit exceeded warning error is displayed only on the one-digit seven-segment LED for error display in the medal count display unit 426b (see FIG. 37B), whose display is controlled by the medal count control board 443. Note that when an upper limit exceeded warning error occurs, the medal counter value does not exceed the first upper limit, so game play is not stopped, and the upper limit exceeded warning error notification function serves to warn the player that the medal counter value is approaching the upper limit. Furthermore, the manner in which the upper limit exceeded warning error is not limited to this example, and for example, the upper limit exceeded warning error may be notified by a one-digit seven-segment error display LED in the medal count display unit 426b (see FIG. 37B), and at the same time, an error code (numbers, letters, etc.) corresponding to the medal counter upper limit exceeded warning error may also be displayed on a two-digit seven-segment payout display LED in the game information display unit 426a (see FIG. 37A), the display of which is controlled by the main control board 441.

The notification function of the medal counter's upper limit exceeding error and upper limit exceeding notice error may be activated when a medal payout request command described later is sent from the main control board 441 to the medal count control board 443. In this case, the medal count control board 443 first adds the payout number added to the medal payout request command described later to the current medal counter value, and determines whether the addition result exceeds the first upper limit value or the second upper limit value. If the addition result exceeds the first upper limit value or the second upper limit value, an error code corresponding to the upper limit exceeding error or the upper limit exceeding notice error is displayed on the one-digit 7-segment LED for error display in the medal count display unit 426b (see FIG. 37B). In addition, if the addition result exceeds the first upper limit value or the second upper limit value, a Nack command to which information indicating the upper limit exceeding error or the upper limit exceeding notice error is added is sent from the medal count control board 443 to the main control board 441 as a response (reply) to the medal payout request command. Then, on the main control board 441 that received the Nack command, if the Nack command includes information about an upper limit exceeded error, an error code corresponding to the upper limit exceeded error is displayed on the two-digit seven-segment LED for payout display in the game information display unit 426a (see FIG. 37A). However, if the Nack command includes information about an upper limit exceeded warning error, the error code corresponding to the upper limit exceeded warning error is not displayed because it would interfere with the progress of the game.

As described above, in the medal counter upper limit exceeding error notification function when the winning combination is determined, if the result of adding the number of game media (game value) to be paid out to the current medal counter value (reserved number) exceeds the first upper limit, the game progress is stopped and an upper limit exceeding error is notified, so that the player can be prompted to settle the stored game media. In addition, in the medal counter upper limit exceeding notice error notification function when the winning combination is determined, an error notification (upper limit exceeding notice error notification) is also performed when the result of adding the number of game media to be paid out to the current medal counter value (reserved number) exceeds the second upper limit, but the game progress is not stopped at this time. Therefore, if such a function for notifying an upper limit exceeding notice error (warning) of the number of stored game media (game value) is provided, the player can be quickly prompted to settle the stored medals before an upper limit exceeding error occurs that would stop the game progress, so that the game can be continued smoothly without stopping the game progress.

[10-8-3. What to do if a medal counter limit exceeding error occurs during lending operation]
The method for dealing with the above-mentioned case where an error occurs in which the medal counter exceeds the upper limit when determining the winning role, can also be applied to cases where adding the number of loaned games to the medal counter value during the loan operation of gaming media causes the upper limit (16369) to be exceeded.

Specifically, if, during a game medium lending operation, adding the lending number to the medal counter value exceeds the upper limit (16369), the medal count control board 443 does not add the lending number to the medal counter value (cancels the lending operation), and notifies the game medium lending device 402 of the occurrence of an upper limit exceeded error, and other peripheral devices (data displays, etc.) connected to the medal count control board 443 or the main control board 441 display the occurrence of an upper limit exceeded error in an error segment, prompting the player to perform a settlement operation. The control state of the medal count control board 443 then transitions to a standby state, and after settlement is completed (after the medal counter value is cleared), if a game medium lending operation is detected again, the lending number is added to the medal counter value.

Also, for example, if, during a game medium lending operation, adding the number of loans to the medal counter value exceeds the upper limit (16,369), the medal count control board 443 does not cancel the lending operation (it retains the loaned number without clearing it), but notifies the game medium lending device 402 of the occurrence of an upper limit exceeded error, and displays the occurrence of an upper limit exceeded error on an error segment on other peripheral devices (such as a data display) connected to the medal count control board 443 or on the main control board 441 side, prompting the player to perform settlement operations. Then, after settlement is completed (after the medal counter value is cleared), the medal count control board 443 adds the retained number of loans (for example, 50) to the medal counter value (0).

Furthermore, for example, if, during a game medium lending operation, adding the number of loans to the medal counter value exceeds the upper limit (16,369), the medal count control board 443 adds the number of loans to the medal counter value, notifies the game medium lending device 402 of the occurrence of an upper limit exceeding error, and also displays the occurrence of an upper limit exceeding error on an error segment on other peripheral devices (such as a data display) connected to the medal count control board 443 or on the main control board 441 side, to notify the player to perform a settlement operation. Then, when settlement is complete (after the medal counter value after addition is cleared), the medal count control board 443 transitions to a standby state.

If a function for dealing with the occurrence of an error in which the number of stored gaming media exceeds the upper limit as described above is provided, it will be possible to properly notify the player that the upper limit has been exceeded and suggest settlement operations. In addition, if a function for dealing with the occurrence of an error in which the number of stored gaming media exceeds the upper limit as described above is provided, it will be possible to introduce and operate a medal-less gaming machine with just a simple modification of the program.

[10-9. Medal count clear sound output function]
In the slot machine 401 of this embodiment, as shown in FIG. 36, the medal count display unit 426b including the 5-digit 7-segment LED for displaying the credits of the game medium is attached to the front side (player side) of the front door 411b. On the other hand, the medal count clear switch 443a is mounted on the medal count control board 443 as shown in FIG. 40, and is therefore provided inside the slot machine 401 (inside the cabinet 411a or on the back side of the front door 411b). Therefore, the medal count clear switch 443a is pressed with the front door 411b open, but in this case, it is difficult for the attendant who presses the medal count clear switch 443a to visually check the credit display of the medal count display unit 426b. In this case, it is difficult to visually check whether the pressing operation has been performed correctly (whether a valid operation has been performed), that is, whether the credit display by the 5-digit 7-segment LED of the medal count display unit 426b has become "00000".

To solve this problem, the pachislot 401 of this embodiment is provided with a function that outputs a specific sound (hereinafter referred to as the "medal count clear sound") when an attendant presses the medal count clear switch 443a, indicating that the switch has been pressed, i.e., that the credit count clear process has begun.

In this embodiment, the medal count (number of stored gaming media) is cleared once when the power is turned on, and the medal count clear sound output function can also be activated once when the power is turned on. Specifically, if an unexpected abnormality occurs in the medal count control (control related to payouts, etc.) related to the management of the stored number of gaming media (number of credits), the power to the pachislot 401 is temporarily turned off, and then the medal count clear switch 443a is pressed. Then, with the medal count clear switch 443a still pressed, the pachislot 401 is powered on and restarted, and the medal count clear sound output function is activated. The processing flow for the medal count clear sound (predetermined sound) output function is as follows:

First, if the medal count clear switch 443a is pressed by an attendant when the power is turned on, the detection signal (medal count clear signal) is output to the medal count control microprocessor 460. Next, based on the medal count clear signal input, the medal count control microprocessor 460 controls the medal count display unit 426b (clears the medal counter to 0) so that the display of the 5-digit 7-segment LED for credit display provided in the medal count display unit 426b becomes "00000" (number of credits = 0). In addition, when the medal count control microprocessor 460 receives a clear check request command from the main control microprocessor 450, it adds data (parameters) indicating the start of clear processing to the Ack command in response to the command and sends (replies) it to the main control microprocessor 450.

Next, the main control microprocessor 450, which has received the data indicating the start of the clearing process, adds the medal count clear switch 443a pressing information (clearing process start information) to the medal count clear start command described below and sends it to the sub-control board 442. Then, the sub-control board 442 (sub-CPU, not shown) which has received the medal count clear start command described below controls the speaker (audio output means) included in the speaker group 429 to start shot playback of the medal count clear sound. The playback (output) period of the medal count clear sound is set in advance. Note that shot playback of the sound means that the operation of outputting the sound from the speaker for the preset playback (output) period is executed only once.

Next, when the pressing operation of the medal count clear switch 443a is finished, the detection signal (medal count clear signal) is output to the medal count control microprocessor 460. Next, when the medal count control microprocessor 460 receives a clear check request command from the main control microprocessor 450, it adds data (parameters) indicating the end of the clear process to the Ack command in response to that command and sends (replies) it to the main control microprocessor 450.

Then, the main control microprocessor 450, which has received the data indicating the end of the clearing process, adds information indicating the end of pressing the medal count clear switch 443a (information indicating the end of the clearing process) to a medal count clearing end command (described below) and transmits it to the sub-control board 442. Then, the sub-control board 442 (sub-CPU, not shown) which has received the medal count clearing end command (described below) controls the speakers included in the speaker group 429 to stop the shot playback of the medal count clear sound.

In the medal count clear sound output function of this embodiment, if the medal count clear switch 443a is kept pressed during the medal count clear sound playback period, the medal count clear sound continues to sound. If the medal count clear switch 443a is kept pressed for a period longer than the medal count clear sound playback period, the medal count clear sound is output for that playback period and then stops. In other words, if the end timing of the clear process is after the medal count clear sound playback period, the medal count clear sound stops before the end of the clear process. On the other hand, if the medal count clear switch 443a is kept pressed for a period shorter than the set playback period of the medal count clear sound, the medal count clear sound also stops when the medal count clear switch 443a is no longer pressed. In other words, if the end timing of the clear process is within the medal count clear sound playback period, the medal count clear sound stops midway through the playback period.

In this embodiment, an example has been described in which the information (parameter) of the medal count clear switch 443a on (start of pressing)/off (end of pressing or no pressing) is added to a dedicated command (medal count clear start command, medal count clear end command) and sent from the main control board 441 to the sub-control board 442, but the present invention is not limited to this. For example, the medal count clear switch 443a on/off information (status information) may be added to a no-operation command and sent from the main control board 441 to the sub-control board 442. The medal count clear sound may be output at the same volume as the error sound, or at a volume adjusted by a volume adjustment function provided in the maintenance menu (so-called hall menu). In this case, for example, the medal count clear sound can be played at a desired volume.

The medal count clear sound may be the same as the error sound, or a dedicated sound. In the latter case, it is desirable to use a voice message such as, "The medal counter reserved in the gaming machine has been cleared."

By providing the above-mentioned medal count clear sound output function, for example, the fact that the number of stored gaming media has been cleared by pressing the medal count clear switch 443a can be notified by the five-digit seven-segment LED for credit display in the medal count display unit 426b, and can also be notified by the medal count clear sound. Therefore, in this case, for example, as in this embodiment, even if a situation occurs in which it is difficult to visually see the display of the five-digit seven-segment LED for credit display in the medal count display unit 426b when a staff member of the gaming establishment presses the medal count clear switch 443a, the staff member of the gaming establishment can be reliably notified that the medal count clear switch 443a has been pressed accurately (a valid operation).

In addition, with the medal count clear sound output function described above, for example, the output of the medal count clear sound is stopped in conjunction with the end of the pressing operation on the medal count clear switch 443a, so a situation does not occur in which the medal count clear sound continues to sound even after the stored number clear process is completed. In addition, with the medal count clear sound output function described above, even if the pressing operation on the medal count clear switch 443a continues for a long time, the medal count clear sound stops at the preset playback (output) period, so a situation does not occur in which the medal count clear sound continues to sound for a long time. This makes it possible to prevent the occurrence of unpleasant situations.

In this embodiment, the embodiment has been described in which the pressing operation of the medal count clear switch 443a is notified using the medal count clear sound, but the present invention is not limited to this. For example, instead of the medal count clear sound, the LED group 435 can be controlled to emit light in a predetermined pattern (medal count clear pattern: not shown) to notify the staff of the pressing operation of the medal count clear switch 443a, although the effect is slightly weaker than that of the medal count clear sound. In this case, specifically, in the registration process of the notification request (S1516, S1519 described later) performed in the non-game progress command process (see FIG. 87 described later), the notification of the medal count clear by the LED group 435 can be executed by setting the registration destination of the notification request to the LED group 435. In addition, when such a notification form is used, the LED group 435 is made to emit light with the front door 411b open, and the staff cannot look directly at the light emission, but since the LED group 435 uses LEDs for performance with high brightness, the staff can recognize that the LED group 435 is emitting light. For example, in addition to notifying the player that the medal count has been cleared by outputting a medal count clear sound, the LED group 435 may emit light to notify the player that the medal count has been cleared. In this case, the effect of reliably notifying the staff at the gaming facility that the medal count has been cleared can be further enhanced.

[10-10. Data input/output mechanism between pachislot and game media lending device]
[10-10-1. Schematic configuration of data input/output mechanism]
In the gaming system 400 of this embodiment, a pachislot 401 (a medalless gaming machine) and a gaming medium lending device 402 (sandwiched device) are connected via GPIO, and a two-wire synchronous bidirectional original protocol is adopted as the data input/output specification (pseudo communication mechanism) between the two.

Figure 49 shows a schematic configuration of the data input/output mechanism between the pachislot 401 and the game media lending device 402 in this embodiment. Note that, to simplify the explanation, Figure 49 shows only the components necessary for data input/output operations between the pachislot 401 and the game media lending device 402.

In this embodiment, the medal count control board 443 in the slot machine 401 is connected to the game media lending device 402 via a connection mechanism 445a (see FIG. 90A described later) provided in the game ball etc. connection terminal board 445. The data input/output operation of the two-wire synchronous method between the medal count control board 443 and the game media lending device 402 is performed using four signal lines as shown in FIG. Specifically, the data input/output mechanism between the medal count control board 443 and the game media lending device 402 is configured by two signal lines (PRDY signal line and EXS signal line) for unidirectionally inputting the PRDY signal (STB (strobe) signal) and the EXS signal (data signal) from the medal count control board 443 to the game media lending device 402, and two signal lines (BRDY signal line and BRQ signal line) for unidirectionally inputting the BRDY signal (STB signal) and the BRQ signal (data signal) from the game media lending device 402 to the medal count control board 443.

The PRDY signal and EXS signal output from the medal count control board 443 to the game medium lending device 402 are input to the control unit 402a (hereinafter referred to as the "peripheral device control unit 402a") via the input/output interface 402b in the game medium lending device 402. In addition, in the gaming system 400, the BRDY signal and BRQ signal generated by the peripheral device control unit 402a are output to the medal count control board 443 (on the pachislot 401 side) via the input/output interface 402b.

Although not shown in FIG. 49, the connection mechanism 445a (game ball etc. connection terminal board 445) is also provided with a signal line for transmitting a signal (hereinafter referred to as the "VL signal") for checking the connection state between the medal count control board 443 and the game medium lending device 402 (see FIG. 88 described below). The VL signal input to the medal count control board 443 is added to an Ack command or Nack command by serial communication and transmitted to the main control board 441.

When there is data (transmission data) to be output from the medal count control board 443 to the game media lending device 402, the medal count control board 443 outputs the EXS signal (transmission data) in units of one bit in data transmission to the game media lending device 402 by synchronizing with the level control (rising or falling edge of the level) of the PRDY signal (STB signal). At this time, the peripheral device control unit 402a (game media lending device 402 side) to which the PRDY signal (STB signal) and the EXS signal (transmission data) are input checks the level ("High" or "Low") of the EXS signal (transmission data) according to the level change of the PRDY signal (STB signal) and acquires the data ("1" or "0") in units of one bit.

On the other hand, when there is data (transmission data) to be output from the game media lending device 402 to the medal count control board 443, the data transmission from the game media lending device 402 to the medal count control board 443 outputs the BRQ signal (transmission data) in units of one bit in synchronization with the level control (rising or falling edge of the level) of the BRDY signal (STB signal). Also, at this time, the medal count control board 443 (on the pachislot 401 side) to which the BRDY signal (STB signal) and the BRQ signal (transmission data) are input checks the level ("High" or "Low") of the BRQ signal (data signal) according to the level change (rising or falling edge of the level) of the BRDY signal (STB signal) and acquires the data ("1" or "0") in units of one bit.

In addition, data input/output between the medal count control board 443 and the game media lending device 402 is performed in a polling format, and in response to a data output (request) from the medal count control board 443 to the game media lending device 402, data is output from the game media lending device 402 to the medal count control board 443 as a response (answer).

In this embodiment, the data output (transmission) operation from the medal count control board 443 to the game media lending device 402 is performed by interrupt processing at 1 msec intervals, and the data output (transmission) operation from the game media lending device 402 to the medal count control board 443 is also performed by interrupt processing at 1 msec intervals. In addition, the data input (reception) operation of the medal count control board 443 of the data output from the game media lending device 402 is performed by interrupt processing at 1 msec intervals, and the data input (reception) operation of the game media lending device 402 of the data output from the medal count control board 443 is also performed by interrupt processing at 1 msec intervals. In addition, in the game system 400 of this embodiment, the 1 msec interrupt processing performed on the medal count control board 443 side and the 1 msec interrupt processing performed on the game media lending device 402 side are not performed in synchronization.

In addition, in this embodiment, an example has been described in which data input/output operations between the medal count control board 443 and the game media lending device 402 are performed by interrupt processing with a cycle of 1 msec. However, since data input/output in 1-bit units can be specified in 1 msec, interrupt processing may be performed with a cycle of, for example, 500 μsec, 200 μsec, or 100 μsec.

[10-10-2. Examples of data input/output operations]
Here, with reference to Fig. 50, the data input/output operation (pseudo communication operation) of the two-line synchronous method between the medal count control board 443 and the game medium lending device 402 will be described. Note that the input/output operation of the PRDY signal (STB signal) and the EXS signal (data signal) is the same as that of the BRDY signal (STB signal) and the BRQ signal (data signal), so Fig. 50 will describe both input/output operations together. In addition, in the example shown in Fig. 50, an example of inputting/outputting (transmitting/receiving) 1-byte data "01010101B" (55H) will be described.

In this example, a 1-bit data signal (so-called positive logic) is input and output in synchronization with the change in level of the STB signal from low to high (rising edge), but the present invention is not limited to this. A 1-bit data signal (so-called negative logic) may also be configured to be input and output in synchronization with the change in level of the STB signal from high to low (falling edge).

In this example, one bit of data is input and output over a period of five interrupt processes (5 msec), during which the level of the STB signal is set to a high level (on state) continuously for three interrupt periods (3 msec), and set to a low level (off state) for the other two interrupt periods (2 msec).

As described above, in this embodiment, data output and data input of each device between the medal count control board 443 and the game media lending device 402 are both performed by interrupt processing with a period of 1 msec. However, since the interrupt processing on the data output side and the interrupt processing on the data input side between the medal count control board 443 and the game media lending device 402 are not performed synchronously, there is a possibility that a shift (period shift) greater than 0 msec and less than 1 msec may occur between the execution timing of the data output and the execution timing of the data input. Therefore, in this embodiment, in the input/output period of 1 bit of data (5 interrupt processing periods), two interrupt periods (2 msec) are provided as the OFF period of the STB signal, and one of these interrupt periods (1 msec) is provided as a margin to accommodate the period shift. In this way, when a margin period of the OFF state is provided for the STB signal, even if a period shift occurs between the output operation and the input operation of the data, the rising edge of the STB signal can be reliably detected on the data input (acquisition) side, and the data can be accurately acquired.

First, we will explain the control of the data output side in the two-wire synchronous method with reference to Figure 50.

When outputting the data "1" of BIT0, first, after the start of the output operation of BIT0, the STB signal is maintained at the OFF state level (Low) until the end of the first interrupt period (until the occurrence of interrupt timing 0 of BIT0). Next, after the end of the first interrupt process, the STB signal is raised (changed to High level) at the second interrupt timing (interrupt timing 0 of BIT0), and the level of the data signal is changed to the level (High level) corresponding to the data "1" of BIT0.

Next, the ON level (High) of the STB signal is maintained for three interrupt periods (3 msec), and the STB signal is lowered (turned OFF) at the fifth interrupt timing (BIT0 interrupt timing 3). At this time, the data signal level (High) is maintained unchanged. After that, the OFF level (Low) of the STB signal is maintained until the end of the fifth interrupt processing (until BIT0 interrupt timing 4 occurs), and the output (transmission) operation of BIT0 is terminated.

After the output operation of BIT0 is completed, the data output side starts outputting data "1" for BIT1. First, after the output operation of BIT0 is completed, the STB signal is maintained at the OFF level (Low) until the first interrupt period ends (until interrupt timing 0 occurs for BIT1).

Next, after the first interrupt process is completed, the STB signal is raised (changed to high level) at the second interrupt timing (interrupt timing 0 of BIT1), and the level of the data signal is changed to a level (low level) corresponding to data "0" of BIT1.

Next, the ON level (High) of the STB signal is maintained for three interrupt periods (3 msec), and the STB signal is lowered (turned OFF) at the fifth interrupt timing (BIT1 interrupt timing 3). At this time, the data signal level (Low) is maintained unchanged. Thereafter, the OFF level (Low) of the STB signal is maintained until the end of the fifth interrupt processing (until BIT1 interrupt timing 4 occurs), and the output (transmission) operation of BIT1 is terminated.

After that, when the same level control of the STB signal and data signal as described above for the data output of BIT0 or BIT1 is performed for the data output of BIT3 to BIT7, the output operation of one byte of data ("01010101B") is completed.

Next, we will explain the control of the data input (acquisition) side in the two-wire synchronization method with reference to Figure 50.

When acquiring the data "1" of BIT0, first, on the data input side, after the start of the input operation of BIT0, the rising edge of the STB signal is detected at a specified interrupt timing (interrupt timing 0 of BIT0), and then, within three interrupt periods (3 msec), the data signal is acquired and the level of the data signal is detected. At this time, since the data of BIT0 is "1", a high level data signal is detected, and as a result, it is determined on the data input side that the data of BIT0 is "1", and the input (acquisition) operation of BIT0 ends.

After the input (acquisition) operation of BIT0 is completed, the input operation of BIT1 is started on the data input side. Then, on the data input side, after the input operation of BIT1 is started, the rising edge of the STB signal is detected again at a specific interrupt timing (interrupt timing 0 of BIT1), and then within three interrupt periods (3 msec), the data signal is acquired and the level of the data signal is detected. At this time, since the data of BIT1 is "0", a low-level data signal is detected, and as a result, it is determined that the data of BIT1 is "0" on the data input side, and the input (acquisition) operation of BIT1 is completed.

After that, when a data acquisition method based on the level detection of the STB signal and data signal, as described above for data input (acquisition) of BIT0 or BIT1, is performed for data input of BIT3 to BIT7, the input (acquisition) operation of one byte of data ("01010101B") is completed.

In the example shown in FIG. 50, the PRDY signal and the BRDY signal are described as STB signals, and the EXS signal and the BRQ signal are described as data signals, but the PRDY signal and the BRDY signal may be data signals, and the EXS signal and the BRQ signal may be STB signals.

If a two-wire synchronous data input/output mechanism (bidirectional protocol) is provided between the above-mentioned pachislot 401 (medal count control board 443) and the game media lending device 402, and the above-mentioned data input/output control is performed between the two devices, it becomes possible to introduce and operate a medal-less gaming machine with just a simple modification of the program.

[10-11. Connection confirmation process between medal count control board and game media lending device at startup]
In the gaming system 400 of this embodiment, as described above, the medal count control board 443 and the game media lending device 402 (sanded device) are connected by GPIO, and data is input and output between them by a two-wire synchronous bidirectional protocol. Here, the contents of the connection confirmation process at startup performed between the medal count control board 443 and the game media lending device 402 (sanded device) will be described with reference to FIG. 51. Note that FIG. 51 is a diagram showing an overview of the processes performed by the medal count control board 443 and the game media lending device 402 in the connection confirmation process at startup, and an overview of the input and output operation of data (commands) performed between the two.

At startup, first, initialization processing is performed on the medal count control board 443 and the game media lending device 402. Next, after the initialization processing is completed, on the medal count control board 443, the two output ports used in the data output operation of the two-wire synchronous method, namely the PRDY signal output port and the EXS signal output port, are both set to the ON state (high level signal). As a result, ON state signals are input to the two input ports used in the data input operation of the two-wire synchronous method in the game media lending device 402, namely the PRDY signal input port and the EXS signal input port (T51).

Next, the game media lending device 402 determines whether the on state of either the PRDY signal input port or the EXS signal input port (the input port to be monitored) is maintained for a predetermined period of time (200 msec in the example shown in Figure 51) or more.

Then, when it is determined that the on state of either the PRDY signal input port or the EXS signal input port (the input port to be monitored) in the game media lending device 402 has been maintained for a predetermined period or more, the two output ports used in the two-wire synchronous data output operation in the game media lending device 402, i.e., the BRDY signal output port and the BRQ signal output port, are both set to the on state (high level signal). As a result, on-state signals are input to the two input ports used in the two-wire synchronous data input operation in the medal count control board 443, i.e., the BRDY signal input port and the BRQ signal input port (T52).

Next, the medal count control board 443 determines whether the on state of either the BRDY signal input port or the BRQ signal input port (the input port to be monitored) is maintained for a predetermined period of time (200 msec in the example shown in Figure 51) or more.

Then, when the medal count control board 443 determines that the on state of either the BRDY signal input port or the BRQ signal input port (the input port to be monitored) is maintained for a predetermined period or longer, the medal count control board 443 determines that the medal count control board 443 and the game medium lending device 402 (sanded device) are normally connected.

Therefore, if the medal count control board 443 in the pachislot 401 and the game media lending device 402 (sandwich device) are not properly connected, the medal count control board 443 will not be able to execute any further processing, and as a result, the main control board 441 will also be unable to play.

The specific processing contents of the connection confirmation control between the medal count control board 443 and the game media lending device 402 (sandwich device) described above will be described in detail later using Figure 70 (flowchart of peripheral device connection confirmation processing performed by the medal count control board 443) and Figure 83 (flowchart of medal count control connection confirmation processing performed by the game media lending device 402).

When a function for checking the connection between the medal count control board 443 and the game media lending device 402 at the time of startup as described above is provided, since a GPIO is used for the data input/output (communication) port between the two, the connection status of the line between the medal count control board 443 and the game media lending device 402 can be easily checked. In addition, when a function for checking the connection between the medal count control board 443 and the game media lending device 402 at the time of startup as described above is provided, it becomes possible to introduce and operate a medalless gaming machine with just a simple modification of the program.

In the connection confirmation process performed between the medal count control board 443 and the game media lending device 402 described above, an example has been described in which the game media lending device 402 monitors the period during which one of the two input ports (the input port for the PRDY signal and the input port for the EXS signal) is kept on, and the medal count control board 443 also monitors the period during which one of the two input ports (the input port for the BRDY signal and the input port for the BRQ signal) is kept on, but the present invention is not limited to this. For example, the game media lending device 402 may monitor the period during which both of the two input ports (the input port for the PRDY signal and the input port for the EXS signal) are kept on, and the medal count control board 443 may also monitor the period during which both of the two input ports (the input port for the BRDY signal and the input port for the BRQ signal) are kept on.

The order of the process of monitoring the two input ports by the medal count control board 443 and the process of monitoring the two input ports by the game media lending device 402 may be reversed. That is, the medal count control board 443 may first monitor the period during which one of the two input ports (the input port for the BRDY signal and the input port for the BRQ signal) is maintained in the on state, and then the game media lending device 402 may monitor the period during which one of the two input ports (the input port for the PRDY signal and the input port for the EXS signal) is maintained in the on state.

[10-12. Control process between medal count control board and game media lending device during lending operation]
Next, with reference to Figures 52 and 53, the contents of the processing carried out between the medal count control board 443 and the game media lending device 402 when a game media lending operation is executed will be described.

FIG. 52 is a schematic diagram of the data input/output mechanism between the slot machine 401 and the game media lending device 402 in the gaming system 400. To simplify the explanation, FIG. 52 mainly shows only the components necessary for the data input/output operation between the slot machine 401 and the game media lending device 402 during the lending operation. FIG. 53 is a diagram showing an overview of the processing performed by the medal count control board 443 and the game media lending device 402 during the lending operation, as well as an overview of the data (command) input/output operation between the two.

First, when the lending button 419 is pressed, the lending switch 419S is turned on, and this detection signal is input from the lending switch 419S to the game media lending device 402 via the game ball etc. connection terminal board 445 (see FIG. 52). At this time, within the game media lending device 402, the peripheral device control unit 402a acquires the detection signal (on state signal) from the lending switch 419S via the input/output interface 402b. As a result, the game media lending device 402 (peripheral device control unit 402a) detects that the lending button 419 has been pressed.

Next, when the game media lending device 402 (peripheral device control unit 402a) detects that the lending button 419 has been pressed, the peripheral device control unit 402a outputs (transmits) a medal lending instruction command, to which the number of game media to be lent out has been added as subsequent data, to the medal count control board 443 via the input/output interface 402b and the game ball etc. connection terminal board 445 (BRDY signal line and BRQ signal line) (T61).

Next, when a medal lending instruction command is input, the medal count control board 443 determines whether or not the command can be accepted. Note that if the current situation is, for example, during play, settlement, return, setting change, an error has occurred, or the number of medals stored has exceeded the upper limit (including after lending), the medal lending instruction command cannot be accepted; otherwise, the medal lending instruction command can be accepted.

If the medal count control board 443 determines that it is not possible to accept the medal lending instruction command, a Nack command (non-acknowledge response command) is output (transmitted) from the medal count control board 443 to the peripheral device control unit 402a via the game ball etc. connection terminal board 445 (PRDY signal line and EXS signal line) and the input/output interface 402b (T62). After that, the control state of the medal count control board 443 transitions to a standby state.

On the other hand, if the medal count control board 443 determines that it can accept the medal loan instruction command, the medal count control board 443 adds the number of loans to the medal counter value, and an Ack command (acknowledge response command) is output (transmitted) from the medal count control board 443 to the peripheral device control unit 402a via the game ball etc. connection terminal board 445 (PRDY signal line and EXS signal line) and the input/output interface 402b (T63). After that, the control state of the medal count control board 443 transitions to a standby state.

In addition, when the game media lending device 402 (peripheral device control unit 402a) acquires (receives) a Nack command as a response command from the medal count control board 443, the control state of the game media lending device 402 (peripheral device control unit 402a) transitions to a standby state. On the other hand, when the game media lending device 402 (peripheral device control unit 402a) acquires (receives) an Ack command as a response command from the medal count control board 443, the game media lending device 402 (peripheral device control unit 402a) subtracts the number of game media (remaining number) by the number of loans, displays the subtracted number on the three-digit seven-segment LED of the medal lending display unit 427a, and then the control state of the game media lending device 402 (peripheral device control unit 402a) transitions to a standby state.

The specific processing contents of the medal count control board 443 and the game media lending device 402 during the above-mentioned lending operation will be described in detail later using Figure 78 (a flowchart of the processing performed by the medal count control board 443 when a medal lending instruction command is received) and Figure 84 (a flowchart of the medal lending processing performed by the game media lending device 402) described below.

If a processing function is provided between the medal count control board 443 and the game media lending device 402 during the above-mentioned lending operation, it becomes possible to introduce and operate a medalless gaming machine with just a simple modification of the program.

[10-13. Control process between medal count control board and game media lending device during settlement operation]
In the gaming system 400, when a settlement operation for gaming media is performed, 2-byte data representing the settlement number is output (transmitted) from the medal count control board 443 to the gaming media lending device 402, and at this time, the data of the lower byte and the data of the upper byte of the settlement number are output (transmitted) separately. Here, with reference to Figures 54 and 55, the processing contents between the medal count control board 443 and the gaming media lending device 402 performed when a settlement operation for gaming media is performed will be described.

Figure 54 is a schematic diagram of the data input/output mechanism between the slot machine 401 and the game media lending device 402 in the gaming system 400. Note that, in order to simplify the explanation, Figure 54 mainly shows only the components necessary for the data input/output operations performed between the slot machine 401 and the game media lending device 402 during the settlement operation. Figure 55 is a diagram showing an overview of the processes performed by the medal count control board 443 and the game media lending device 402 during the settlement operation, as well as an overview of the data (command) input/output operations performed between the two.

First, when the settlement button 418 is pressed, the settlement switch 418S is turned on, and this detection signal is input from the settlement switch 418S to the medal count control board 443 (see FIG. 54). As a result, the medal count control board 443 detects that the settlement button 418 has been pressed.

Next, when the medal count control board 443 detects that the settlement button 418 has been pressed, a medal count (lower) instruction command, to which the lowest byte of the 2-byte data representing the settlement number of gaming media has been added as subsequent data, is output (transmitted) from the medal count control board 443 to the peripheral device control unit 402a in the gaming media lending device 402 via the gaming ball etc. connection terminal board 445 (PRDY signal line and EXS signal line) and the input/output interface 402b (T71).

Next, when a medal count (lower) instruction command is input in the gaming media lending device 402 (peripheral device control unit 402a), it is determined whether or not settlement can be accepted. Note that if the current status is, for example, during lending, during startup, or some kind of abnormality has occurred within the gaming media lending device 402, settlement cannot be accepted; otherwise, settlement can be accepted.

If the gaming media lending device 402 (peripheral device control unit 402a) determines that the settlement cannot be accepted, a Nack command (non-acknowledge response command) is output (transmitted) from the peripheral device control unit 402a to the medal count control board 443 via the input/output interface 402b and the gaming ball etc. connection terminal board 445 (BRDY signal line and BRQ signal line) (T72). Then, the control state of the gaming media lending device 402 (peripheral device control unit 402a) transitions to a standby state.

On the other hand, if the peripheral device control unit 402a determines that the settlement can be accepted, an Ack command (acknowledgement response command) is output (transmitted) from the peripheral device control unit 402a to the medal count control board 443 via the input/output interface 402b and the game ball connection terminal board 445 (BRDY signal line and BRQ signal line) (T73). Then, the control state of the game medium lending device 402 (peripheral device control unit 402a) transitions to a standby state.

Next, when the medal count control board 443 acquires (receives) a Nack command as a response command from the game media lending device 402, the control state of the medal count control board 443 transitions to a standby state. On the other hand, when the medal count control board 443 acquires (receives) an Ack command as a response command from the game media lending device 402, a medal count (upper) instruction command to which the upper 1 byte of the settlement number is added as subsequent data is output (transmitted) from the medal count control board 443 to the peripheral device control unit 402a in the game media lending device 402 via the game ball etc. connection terminal board 445 (PRDY signal line and EXS signal line) and the input/output interface 402b (T74).

Then, the medal counter value is cleared in the medal count control board 443, and a medal count completion command is output (transmitted) from the medal count control board 443 to the peripheral device control unit 402a in the game medium lending device 402 via the game ball etc. connection terminal board 445 (PRDY signal line and EXS signal line) and the input/output interface 402b (T75). After that, the control state of the medal count control board 443 transitions to a standby state.

On the other hand, when the game media lending device 402 (peripheral device control unit 402a) acquires (receives) the medal count (higher level) instruction command and the medal count completion command in this order, the control state of the game media lending device 402 (peripheral device control unit 402a) transitions to a standby state.

In the example shown in FIG. 55, after the medal count control board 443 transmits the medal count (upper) instruction command and the medal count completion command, the game media lending device 402 (peripheral device control unit 402a) does not transmit an Ack command or a Nack command. This is for the following reason. When the game media lending device 402 (peripheral device control unit 402a) receives the medal count (lower) instruction command and transmits the Ack command, there is no longer any cause for interrupting the settlement process. In this case, even if a process is provided in which the game media lending device 402 that has received the medal count (upper) instruction command and the medal count completion command transmits a response command, the game media lending device 402 will not transmit a Nack command as a response command, and inevitably only the Ack command transmission process is performed. Therefore, since the process of sending this response command is not necessarily required, in the example shown in FIG. 55, in order to eliminate the waste of this process, the process of sending the response command from the gaming media lending device 402 (peripheral device control unit 402a) after receiving the medal count (higher level) instruction command and the medal count completion command is omitted.

The specific processing contents of the medal count control board 443 and the game media lending device 402 during the above-mentioned settlement operation will be described in detail later using Figure 77 (a flowchart of the processing performed by the medal count control board 443 when the settlement switch is pressed) and Figure 85 (a flowchart of the medal counting (settlement) processing performed by the game media lending device 402) described later.

If a processing function is provided between the medal count control board 443 and the game media lending device 402 during the settlement operation described above, it will be possible to introduce and operate a medalless gaming machine with just a simple modification of the program.

[10-14. Settlement operation for gaming media using settlement button and return button]
As shown in FIG. 39, the gaming system 400 has a configuration in which an adjustment switch 418S is connected to a medal count control board 443, and a return switch 420S is connected to a main control board 441.

In a gaming system 400 configured as described above, when the settlement button 418 is pressed, the medal counter value (number of medals inserted) in the medal count control board 443 is output (transmitted) to the gaming medium lending device 402 (peripheral device) while maintaining the value (number of medals inserted), and then the medal counter value is cleared (set to "0"). Also, in the gaming system 400, when the return button 420 is pressed, the medal counter value (number of medals inserted) in the medal count control board 443 is added to the medal counter value (number of medals inserted), and then the medal counter value is cleared (set to "0").

Therefore, for example, when settling all currently stored gaming media and gaming media that have been bet (deposited), the settlement button 418 is pressed to send the medal counter value (stored number) to the gaming media lending device 402 (peripheral device), and then the return button 420 and the settlement button 418 are pressed in that order (first settlement procedure), or the return button 420 is pressed to add the deposit counter value (deposited number) to the medal counter value (stored number), and then the settlement button 418 is pressed (second settlement procedure).

As an example, consider the case where the current value of the input counter (number of inputs) is "3", the value of the medal counter (number of medals stored) is "59", and the number of gaming media that has been sent (settlement completed) to the gaming media lending device 402 (peripheral device) is "0".

When the first settlement procedure described above is adopted for the above case, first, the settlement button 418 is pressed. As a result, the value of the input counter (number of inputs) is maintained at "3", the value of the medal counter (number of reserved medals) is "0", and the number of game media already sent (settled) to the game media lending device 402 is "59". Next, when the return button 420 is pressed, the value of the input counter (number of inputs) is "0", the value of the medal counter (number of reserved medals) is "3", and the number of game media already sent (settled) to the game media lending device 402 is maintained at "59". Next, when the settlement button 418 is pressed, the value of the input counter (number of inputs) is maintained at "0", the value of the medal counter (number of reserved medals) is "0", and the number of game media already sent (settled) to the game media lending device 402 is "62".

On the other hand, if the second settlement procedure described above is adopted for the above case, first the return button 420 is pressed. As a result, the value of the input counter (number of inputs) becomes "0", the value of the medal counter (number of medals stored) becomes "62", and the number of game media that have been sent (settled) to the game media lending device 402 is maintained at "0". Then, when the settlement button 418 is pressed, the value of the input counter (number of inputs) is maintained at "0", the value of the medal counter (number of medals stored) becomes "0", and the number of game media that have been sent (settled) to the game media lending device 402 is "62".

When the settlement operation for gaming media using the settlement button 418 and return button 420 described above is used, it becomes possible to introduce and operate a medal-less gaming machine with only simple modifications to the program.

[10-15. Various Modifications of Gaming Media Settlement Mode]
As described above, the gaming system 400 of this embodiment has a configuration in which the settlement switch 418S is connected to the medal count control board 443 and the return switch 420S is connected to the main control board 441, and the procedure for pressing the settlement button 418 and the return button 420 when settling the gaming media (settlement operation of the gaming media) employs the first or second settlement procedure described above. However, the connection configuration of the settlement button 418 and the return button 420, and the procedure for pressing the settlement button 418 and the return button 420 when settling the gaming media, i.e., the settlement mode of the gaming media, are not limited to the above-mentioned example modes, and may employ, for example, various modified modes (other settlement mode examples 1 to 3) as follows.

<Other settlement example 1>
For example, the gaming system may be configured to have only the settlement button 418 connected to the medal count control board 443, without the return button 420, and the settlement operation may be as follows: Here, consider a case where the number of gaming media inserted (number of bets) before the settlement button 418 is pressed is "3", the medal counter value (reserved number) is "59", and the number of gaming media sent (settled) to the gaming media lending device 402 (peripheral device) is "0".

In a gaming system in this situation, when the settlement button 418 is pressed, the medal count control board 443 first inquires of the main control board 441 about the number of gaming media inserted (number of bets). This inquiry is made using ports and signal lines (ports and signal lines other than the ports and signal lines used for the gaming media status function) that are capable of inputting and outputting data via GPIO and are provided between the main control board 441 and the medal count control board 443. Next, in response to this inquiry from the medal count control board 443, the main control board 441 replies with information that the number of gaming media inserted is "3", and then clears the number of gaming media inserted managed by the main control board 441 (sets it to "0").

Next, the medal count control board 443, which has received information that the number of game media inserted is "3", adds "3" to the medal counter value. As a result, the medal counter value is updated to "62". At this point, the number of game media that has been settled remains at "0".

Next, the medal count control board 443 performs a settlement process, which causes the medal counter value to become "0" and the number of settled gaming media to become "62."

<Another settlement example 2>
For example, the gaming system may be configured to have only the settlement button 418 connected to the main control board 441, without the return button 420, and the settlement operation may be as follows: Here, consider a case where the number of gaming media inserted (number of bets) before the settlement button 418 is pressed is "3", the medal counter value (reserved number) is "59", and the number of gaming media sent (settled) to the gaming media lending device 402 (peripheral device) is "0".

In a gaming system in this situation, when the settlement button 418 is pressed, first, information indicating that the number of gaming media inserted is "3" is sent from the main control board 441 to the medal count control board 443, and then the number of gaming media inserted managed by the main control board 441 is cleared (set to "0").

Next, the medal count control board 443, which has received information that the number of game media inserted is "3", adds "3" to the medal counter value. As a result, the medal counter value is updated to "62". At this point, the number of game media that has been settled remains at "0".

Next, information that settlement processing will be performed is sent from the main control board 441 to the medal count control board 443. The medal count control board 443, which has received the information that settlement processing will be performed, performs the settlement processing, thereby updating the medal counter value to "0" and the number of settled gaming media to "62".

<Other settlement example 3>
For example, the gaming system may be configured to include a return button 420 and a settlement button 418 connected to the main control board 441, and the settlement operation may be as follows: Here, consider a case where the number of gaming media inserted (number of bets) before the settlement button is pressed is "3", the medal counter value (number of reserved medals) is "59", and the number of gaming media sent (settled) to the gaming media lending device 402 (peripheral device) is "0".

In a gaming system in this situation, when the return button 420 is pressed for the first time, information indicating that the number of gaming media inserted is "3" is sent from the main control board 441 to the medal count control board 443, and then the number of gaming media inserted managed by the main control board 441 is cleared (set to "0").

Next, the medal count control board 443, which has received information that the number of game media inserted is "3", adds "3" to the medal counter value. As a result, the medal counter value is updated to "62". At this point, the number of game media that has been settled remains at "0".

Next, when the settlement button 418 is pressed, a settlement process is performed on the medal count control board 443, which updates the medal counter value to "0" and the number of settled gaming media to "62."

In this case, the following settlement procedure (procedure for updating various counters) may be adopted:

When the settlement button 418 is pressed for the first time, a settlement process is carried out on the medal count control board 443, whereby the number of gaming media inserted (number of bets) managed by the main control board 441 is maintained at "3", the medal counter value is updated to "0", and the number of settled gaming media is updated to "59".

Next, when the return button 420 is pressed, information that the number of game media inserted is "3" is sent from the main control board 441 to the medal count control board 443, and the number of game media inserted managed by the main control board 441 is then cleared (set to "0"). Next, the medal count control board 443, which has received the information that the number of game media inserted is "3", adds "3" to the medal counter value. As a result, the medal counter value is updated to "3", and the number of game media that has been settled is maintained at "59".

Next, when the settlement button 418 is pressed, a settlement process is performed on the medal count control board 443, whereby the medal counter value is updated to "0" and the number of settled gaming media is updated to "62".

[10-16. Chip individual number transmission process]
In the gaming system 400, at startup, the chip individual number of the main control microprocessor 450 in the main control board 441 (hereinafter referred to as the "main control chip individual number"), or the chip individual number of the medal count control microprocessor 460 in the medal count control board 443 (hereinafter referred to as the "medal count control chip individual number") is transmitted to a management computer (hall computer: not shown) located outside the gaming system 400 via the gaming medium lending device 402 (peripheral device).

Now, with reference to Figure 56, we will explain the content of the processing carried out by the main control board 441, medal count control board 443, and game media lending device 402 when the chip individual number is transmitted. Note that Figure 56 is a diagram showing an overview of the processing carried out by each of the main control board 441, medal count control board 443, and game media lending device 402 when the chip individual number is transmitted, as well as an overview of the input/output operation of data (commands) between the three.

At startup, first, the main control chip individual number (4 bytes of data) of the main control microprocessor 450 is read in the main control board 441. In addition, the medal count control chip individual number (4 bytes of data) of the medal count control microprocessor 460 is read in the medal count control board 443.

Next, the main control chip individual number (4 bytes of data) of the main control microprocessor 450 read by the main control board 441 is sent to the medal count control board 443 (T81). At this time, the main control chip individual number is sent one byte at a time (sent four times).

Next, after all data of the main control chip individual number is received by the medal count control board 443, one of the main control chip individual number and the medal count control chip individual number acquired by the medal count control board 443 is transmitted to the game media lending device 402 (T82). At this time, the chip individual number is transmitted one byte at a time (transmission count is four times).

Then, after the game media lending device 402 receives the chip individual number, the received chip individual number (main control chip individual number or medal count control chip individual number) is transmitted from the game media lending device 402 to an external management computer (T83). At this time, the chip individual number is transmitted to the external management computer.

The specific contents of the above-mentioned chip individual number transmission process performed by the main control board 441, medal count control board 443, and game media lending device 402 at startup will be described in detail later using Figure 58 (flowchart of power-on processing performed by the main control board 441), Figure 71 (flowchart of startup command reception processing performed by the medal count control board 443), Figure 72 (flowchart of peripheral device identification code transmission processing performed by the medal count control board 443), and Figure 83 (flowchart of medal count control connection confirmation processing performed by the game media lending device 402).

In the gaming system 400 of this embodiment, an example has been described in which the main control chip individual number or the medal count control chip individual number is sent from the main control board 441 to the management computer via the medal count control board 443 and the gaming media lending device 402 at startup, but the present invention is not limited to this. At startup, both the main control chip individual number and the medal count control chip individual number may be sent from the main control board 441 to the management computer via the medal count control board 443 and the gaming media lending device 402. In this case, a total of 8 bytes of the chip individual number is sent from the medal count control board 443 to the management computer via the gaming media lending device 402.

[10-17. Operation of the main control board (main control microprocessor)]
Next, referring to Figures 57 to 67, the contents of various processes executed by the main CPU 501 (CPU 501 provided in the microprocessor MP described in Figure 43) of the main control board 441 (main control microprocessor 450) using a program will be described.

[10-17-1. Main operation processing of Pachislot under the control of the main CPU]
First, the procedure of the main operation processing (processing after power-on) of the pachislot 401 performed under the control of the main CPU 501 will be explained with reference to the flowchart shown in Figure 57 (hereinafter referred to as the main flow).

First, the main CPU 501 performs power-on processing (S1001). In this processing, the main CPU 501 mainly performs initialization processing, and processing for registering the transmission of a start-up confirmation command that includes data such as the chip individual number. Details of the power-on processing will be described later with reference to FIG. 58.

Next, the main CPU 501 determines whether the setting key switch 432 is in the ON state (S1002). Note that the setting key (not shown) inserted into the setting key switch 432 is an operation key for operating the settings of the slot machine 401 (e.g., settings 1 to 6), and when the setting key is ON, the setting key switch 432 is in the ON state.

When the main CPU 501 determines in S1002 that the setting key switch 432 is on (YES in S1002), the main CPU 501 performs setting change processing (S1003). In this processing, the main CPU 501 performs setting change and/or confirmation processing, and also performs command transmission registration processing at the start and end of the setting change. Details of the setting change processing will be described later with reference to FIG. 59.

Next, the main CPU 501 performs a game start preparation process (S1004). In this process, the main CPU 501 performs a process of determining whether or not a game start condition is met. Details of the game start preparation process will be described later with reference to FIG. 60.

Then, the main CPU 501 performs a medal return process (S1005). In this process, the main CPU 501 performs a process of determining whether or not the player has pressed the return button 420 (whether or not the return switch 420S is in the on state). Details of the medal return process will be described later with reference to FIG. 61.

Then, the main CPU 501 performs a game start process (S1006). In this process, the main CPU 501 performs a process of determining whether or not a game can be started, and a process of registering (setting) a game start request command to be sent to the medal count control board 443. Details of the game start process will be described later with reference to FIG. 62.

Next, the main CPU 501 determines whether or not it is time to start playing (S1007). In the pachislot 401, when an Ack command (acknowledge response command) is received from the medal count control board 443 in response to a game start request command sent from the main CPU 501 to the medal count control board 443 (medal count control CPU 501), the main CPU 501 determines that it is time to start playing, and S1007 results in a YES judgment.

When the main CPU 501 determines in S1007 that game play has not started (if S1007 returns a NO judgment), the main CPU 501 returns the process to S1004 (game start preparation process) and repeats the processes from S1004 onwards.

On the other hand, when the main CPU 501 determines in S1007 that game play has started (if S1007 is a YES determination), the main CPU 501 performs in-game processing (S1008). In this processing, the main CPU 501 performs various main processes related to the progress of the game from the start of the game to the stopping of all reels. Specifically, the main CPU 501 mainly performs random number value acquisition processing, internal lottery processing, reel spin start processing, and reel stop control processing, in that order. Also, in this processing, the main CPU 501 performs transmission registration processing (generation and storage processing) of various commands to be transmitted to the sub-control board 442 at appropriate predetermined timing in accordance with the progress of the game. In addition, the various commands registered (saved) in this process in a communication data storage area (not shown) in the main RAM 503 (for secondary control transmission) are transmitted from the main CPU 501 (main control board 441) to the secondary control board 442 in a secondary control transmission process within a periodic interrupt process (1.1172 msec period) described later in FIG. 65.

After processing S1008, the main CPU 501 performs a game end process (S1009). In this process, the main CPU 501 mainly performs a process of determining a winning combination, a process of updating the game status, etc. Details of the game end process will be described later with reference to FIG. 63.

Next, the main CPU 501 performs a game medal payout process (S1010). In this process, the main CPU 501 mainly performs a registration process of a medal payout request command to be sent to the medal count control board 443 (medal count control CPU 501). The medal payout request command includes data (subsequent data) on the number of game media to be paid out corresponding to the winning combination determination result in S1009. Details of the game medal payout process will be described later with reference to FIG. 64. Then, after processing S1010, the main CPU 501 returns the process to S1004 (game start preparation process) and repeats the processes from S1004 onwards.

Now, returning to the process of S1002 again, when the main CPU 501 determines in S1002 that the setting key switch 432 is not in the ON state (if S1002 is a NO determination), the main CPU 501 performs a game resumption preparation process (S1011). In this process, the main CPU 501 performs a process of setting various game parameters, various flags, various counters, etc. so that the game state is the state at the time of the power outage. Then, as a result of this process, game play is resumed from the game state at the time of the power outage (resuming from a process equivalent to any one of S1004 to S1010).

[10-17-2. Power-on processing (main control)]
Next, the power-on process (main control) performed in S1001 of the main flow (see FIG. 57) will be described with reference to Fig. 58. Fig. 58 is a flow chart showing the procedure of the power-on process (main control).

First, the main CPU 501 performs an initialization process (S1021). In this process, the main CPU 501 initializes the device settings of the main CPU 501. In this process, the timer circuit 513 and the serial communication circuit 514 (SCU0 to 3) are also initialized.

Next, the main CPU 501 refers to the unique information 509 to obtain the chip individual number (4 bytes of data) (S1022).

Next, the main CPU 501 sets the retransmission counter to "5" (S1023). The retransmission counter is a counter for counting the number of transmissions (retransmissions) of a startup confirmation command, described below, from the main control board 441 to the medal count control board 443 (medal count control CPU 501). In this embodiment, when the number of transmissions of the startup confirmation command, described below, reaches five, the main CPU 501 determines that an abnormality has occurred in the communication between the main control board 441 (main CPU 501) and the medal count control board 443 (medal count control CPU 501).

Next, the main CPU 501 performs a transmission registration process for the start confirmation command to be sent to the medal count control board 443 (medal count control CPU 501) (S1024). In the pachislot 401, the start confirmation command is set with command type information and one byte of chip individual number data (subsequent data). Also, since data communication between the main control board 441 (main CPU 501) and the medal count control board 443 (medal count control CPU 501) is performed in 1-byte units, in the start confirmation command transmission process, the chip individual number data is sent (or resent) in four separate 1-byte chunks.

If the process of S1024 is performed after a NO judgment in S1028 described later, the same data as the 1-byte data of the chip individual number set in the previous process of S1024 is set as the subsequent data. Also, if the process of S1024 is the initial start confirmation command transmission registration process, the first byte data of the chip individual number is set as the subsequent data in the start confirmation command. Furthermore, if the process of S1024 is performed after a NO judgment in S1030 described later, the second byte to the fourth byte data of the chip individual number are set in this order for each process of S1024. Also, the start confirmation command registered (saved) in the communication data storage area (for medal count control transmission) not shown in the figure in the main RAM 503 in this process is transmitted from the main control board 441 to the medal count control board 443 in the medal count control transmission process in the fixed cycle interrupt process (1.1172 msec cycle) described in FIG. 65 described later.

Then, the main CPU 501 performs a response waiting process (S1025). In this process, the main CPU 501 transmits a startup confirmation command to the medal count control board 443, and waits until there is some kind of response from the medal count control board 443 to that command. Note that the reception process (monitoring) of the response from the medal count control board 443 is performed by a reception interrupt process (irregularly) that will be described later in FIG. 67.

Next, the main CPU 501 judges whether or not an Ack command (acknowledgement response command) has been received from the medal count control board 443 (S1026). In this judgment process, if the main CPU 501 receives an Ack command from the medal count control board 443, the judgment is YES. On the other hand, if the main CPU 501 receives a Nack command (non-acknowledgement response command) from the medal count control board 443, if a reception error (e.g., parity error, framing error, etc.) occurs, or if a timeout occurs (e.g., if there is no reply from the medal count control board 443 within 200 msec), the judgment process of S1026 is NO. Note that the YES/NO judgment conditions in the judgment process of S1026 are also used in the judgment process of whether or not an Ack command (acknowledgement response command) has been received, which is executed in the various processes described below.

When the main CPU 501 determines in S1026 that an Ack command has been received (if S1026 returns a YES determination), the main CPU 501 performs the processing of S1030, which will be described later.

On the other hand, when the main CPU 501 determines in S1026 that an Ack command has not been received (if S1026 returns NO), the main CPU 501 decrements the value of the retransmission counter by 1 (S1027). Next, the main CPU 501 determines whether the value of the retransmission counter is "0" (S1028).

When the main CPU 501 determines in S1028 that the value of the retransmission counter is not "0" (if S1028 returns a NO determination), the main CPU 501 returns the process to S1024 (start-up confirmation command transmission registration process) and repeats the processes from S1024 onwards.

On the other hand, when the main CPU 501 determines in S1028 that the value of the resend counter is "0" (if S1028 returns a YES determination), the main CPU 501 determines that an abnormality has occurred in the communication between the main control board 441 (main CPU 501) and the medal count control board 443 (medal count control CPU 501), and performs a predetermined error process corresponding to the abnormality (S1029). The main CPU 501 then waits until the error is resolved.

Now, returning to the processing of S1026 again, if S1026 is judged as YES, the main CPU 501 judges whether the transmission process of 4 bytes of data (all data of the chip individual number) is completed (S1030).

When the main CPU 501 determines in S1030 that the transmission process of the 4 bytes of data (all data of the chip individual number) is not complete (if S1030 returns NO), the main CPU 501 returns the process to S1023 (the process of setting the retransmission counter) and repeats the processes from S1023 onwards.

On the other hand, when the main CPU 501 determines in S1030 that the transmission process of 4 bytes of data (all data of the chip individual number) is complete (if S1030 returns a YES determination), the main CPU 501 ends the power-on process and transfers the process to S1002 of the main flow (see FIG. 57).

[10-17-3. Setting change processing]
Next, the setting change processing performed in S1003 of the main flow (see FIG. 57) will be described with reference to Fig. 59. Note that Fig. 59 is a flow chart showing the procedure of the setting change processing.

First, the main CPU 501 performs a transmission registration process for a setting change start command to be transmitted to the medal count control board 443 (S1041). In this embodiment, command type information and setting information (1 byte: subsequent data) indicating the setting are set in the setting change start command. Note that the setting change start command registered (saved) in this process in a communication data storage area (not shown) in the main RAM 503 (for medal count control transmission) is transmitted from the main control board 441 to the medal count control board 443 in a medal count control transmission process in a fixed-cycle interrupt process (1.1172 msec cycle) described in FIG. 65 below.

Then, the main CPU 501 performs a response waiting process (S1042). In this process, the main CPU 501 transmits a setting change start command to the medal count control board 443, and waits until there is some kind of response from the medal count control board 443 to the command. Note that the reception process (monitoring) of the response from the medal count control board 443 is performed by a reception interrupt process (irregularly) that will be described later in FIG. 67.

Next, the main CPU 501 determines whether or not an Ack command has been received from the medal count control board 443 (S1043).

When the main CPU 501 determines in S1043 that an Ack command has not been received (if S1043 returns a NO determination), the main CPU 501 returns the process to S1041 (the process of registering the transmission of the setting change start command) and repeats the processes from S1041 onwards.

On the other hand, when the main CPU 501 determines in S1043 that it has received an Ack command (YES in S1043), the main CPU 501 performs a transmission registration process (generation and storage process) of the setting change command (start) to be transmitted to the sub-control board 442 (S1044). Note that the setting change command (start) registered (saved) in this process in a communication data storage area (for sub-control transmission) not shown in the figure in the main RAM 503 is transmitted from the main CPU 501 (main control board 441) to the sub-control board 442 in a sub-control transmission process in a fixed-period interrupt process (1.1172 msec period) described in FIG. 65 below.

Next, the main CPU 501 performs a setting change confirmation process (at the start) (S1045). In this process, the main CPU 501 changes and/or confirms the settings. Specifically, the settings (e.g., settings 1 to 6) stored in the main RAM 503 are displayed on a two-digit seven-segment LED for payout display on the game information display unit 426a, and when the reset switch 433 is pressed, the settings are updated in ascending order, and when the start lever 422 is pressed with the value to be set displayed, the setting is confirmed. Then, when the setting key (not shown) is turned off, the setting change operation ends, and the main CPU 501 clears any range other than the area in which the settings are stored in the main RAM 503.

Next, the main CPU 501 performs a transmission registration process (S1046) of a setting change end command to be transmitted to the medal count control board 443. In this embodiment, the setting change end command includes command type information and setting information (1 byte: subsequent data) indicating the setting.
In addition, the setting change end command registered (saved) in this process in a communication data storage area (not shown) in the main RAM 503 (for medal count control transmission) is transmitted from the main control board 441 to the medal count control board 443 in a medal count control transmission process within a fixed-period interrupt process (1.1172 msec period) described in Figure 65 below.

Then, the main CPU 501 performs a response waiting process (S1047). In this process, the main CPU 501 transmits a setting change end command to the medal count control board 443, and waits until there is some kind of response from the medal count control board 443 to that command. Note that the reception process (monitoring) of the response from the medal count control board 443 is performed by a reception interrupt process (irregularly) that will be described later in FIG. 67.

Next, the main CPU 501 determines whether or not an Ack command has been received from the medal count control board 443 (S1048).

When the main CPU 501 determines in S1048 that an Ack command has not been received (if S1048 returns a NO determination), the main CPU 501 returns the process to S1046 (the process of registering the transmission of the setting change end command) and repeats the processes from S1046 onwards.

On the other hand, when the main CPU 501 determines in S1048 that it has received an Ack command (YES in S1048), the main CPU 501 performs a transmission registration process (generation and storage process) of the setting change command (end) to be transmitted to the sub-control board 442 (S1049). The setting change command (end) registered (saved) in the communication data storage area (for sub-control transmission) not shown in the main RAM 503 in this process is transmitted from the main CPU 501 (main control board 441) to the sub-control board 442 in a sub-control transmission process in a fixed-period interrupt process (1.1172 msec period) described in FIG. 65 below. Then, after the process of S1049, the main CPU 501 ends the setting change process and moves the process to the process of S1004 in the main flow (see FIG. 57).

[10-17-4. Game Start Preparation Processing]
Next, the game start preparation process performed in S1004 of the main flow (see FIG. 57) will be described with reference to Fig. 60. Fig. 60 is a flow chart showing the procedure of the game start preparation process.

First, the main CPU 501 determines whether the VL signal, which is a connection signal for checking the connection with the game media lending device 402, is in the ON state (S1051).

When the main CPU 501 determines in S1051 that the VL signal is not on (if S1051 is a NO judgment), the main CPU 501 ends the game start preparation process and moves the process to S1005 of the main flow (see FIG. 57). In other words, if the VL signal is not on when the game starts (if a situation occurs in which the connection to the game media lending device 402 cannot be confirmed), the game does not start.

On the other hand, in S1051, when the main CPU 501 determines that the VL signal is in the ON state (if S1051 is determined as YES), the main CPU 501 determines whether the maximum specified number ("3") of gaming media has been inserted (S1052).

When the main CPU 501 determines in S1052 that the maximum number of gaming media has been inserted (if S1052 returns YES), the main CPU 501 performs the process of S1060, which will be described later.

On the other hand, when the main CPU 501 determines in S1052 that the maximum prescribed number of gaming media has not been inserted (if S1052 returns NO), the main CPU 501 determines whether the MAX BET button 416 is enabled and whether the MAX BET button 416 has been pressed (hereinafter simply referred to as the "determination condition for S1053") (S1053).

In addition, whether the MAX BET button 416 is pressed or not is determined based on the on/off state of the MAX BET switch 416S, and when the MAX BET switch 416S is in the on state, it is determined that the MAX BET button 416 is pressed. In addition, the validity/invalidity of the MAX BET button 416 is determined based on 2-bit data (the gaming medium state output from the medal count control board 443 to the main control board 441) composed of the first and second control state signals detected by the above-mentioned gaming medium state function. For example, if the maximum specified number of gaming media is "3" and the current number of gaming media inserted managed by the main control board 441 is "0", it is determined to be valid if the gaming medium state composed of the first and second control state signals is "11B" (when the value of the medal counter provided on the medal count control board 443 is "3" or more), and it is determined to be invalid if it is in any other gaming medium state. Also, for example, if the maximum number of gaming media specified is "3" and the number inserted is "1", then if the gaming media state is "11B" or "10B" (when the medal counter value is "3" or greater or "2"), it is determined to be valid, and if it is in any other gaming media state, it is determined to be invalid.

When the main CPU 501 determines in S1053 that the condition for the determination in S1053 is not met (if S1053 is a NO determination), the main CPU 501 performs the process of S1060 described below. On the other hand, when the main CPU 501 determines in S1053 that the condition for the determination in S1053 is met (if S1053 is a YES determination), the main CPU 501 sets the number of transmissions (any of 3 times to 1 time) to a value obtained by subtracting the current number of game media inserted (any of 0 to 2) from the maximum specified number of game media ("3" in this embodiment) (S1054).

Next, the main CPU 501 performs a process for registering the transmission of a medal insertion request command for the medal insertion count of "1" to be transmitted to the medal count control board 443 (S1055). In the slot machine 401, the medal insertion request command is set with command type information and the insertion count (fixed to "1" in the slot machine 401: subsequent data). That is, in the slot machine 401, when the MAX BET button 416 is pressed, the medal insertion request command is transmitted the number of times set in S1054. Note that the medal insertion request command registered (saved) in a communication data storage area (for medal count control transmission) not shown in the figure in the main RAM 503 in this process is transmitted from the main control board 441 to the medal count control board 443 in the medal count control transmission process in the fixed cycle interrupt process (1.1172 msec cycle) described in FIG. 65 below.

Next, the main CPU 501 performs a response waiting process (S1056). In this process, the main CPU 501 transmits a medal insertion request command to the medal count control board 443, and waits until there is some kind of response from the medal count control board 443 to that command. The reception process (monitoring) of the response from the medal count control board 443 is performed by a reception interrupt process (irregularly) that will be described later in FIG. 67. In addition, when an Ack command is received in response to the medal insertion request command from the medal count control board 443, the main CPU 501 sets the insertion number (the value of the insertion counter) added to the Ack command to the number of game media inserted that is managed by the main control board 441.

Next, the main CPU 501 determines whether or not an Ack command has been received from the medal count control board 443 (S1057).

When the main CPU 501 determines in S1057 that an Ack command has not been received (if S1057 returns a NO determination), the main CPU 501 returns the process to S1055 (the process of registering the transmission of the medal insertion request command) and repeats the process from S1055 onwards.

On the other hand, when the main CPU 501 determines in S1057 that an Ack command has been received (if S1057 is a YES determination), the main CPU 501 subtracts 1 from the number of transmissions (S1058). Next, the main CPU 501 determines whether the number of transmissions is "0" (S1059).

When the main CPU 501 determines in S1059 that the number of transmissions is not "0" (if S1059 is a NO judgment), the main CPU 501 returns the process to S1055 (the process of registering the transmission of the medal insertion request command) and repeats the process from S1055 onwards. On the other hand, when the main CPU 501 determines in S1059 that the number of transmissions is "0" (if S1059 is a YES judgment), the main CPU 501 ends the game start preparation process and moves the process to the process of S1005 of the main flow (see FIG. 57).

Now, returning to the processing of S1052 or S1053 again, if S1052 is judged as YES or S1053 is judged as NO, the main CPU 501 judges whether the 1 bet button 417 is valid and whether the 1 bet button 417 has been pressed (hereinafter simply referred to as the "judgment condition of S1060") (S1060).

Whether the 1 bet button 417 has been pressed is determined based on the on/off state of the 1 bet switch 417S, and if the 1 bet switch 417S is on, it is determined that the 1 bet button 417 has been pressed. Also, whether the 1 bet button 417 is valid or invalid is determined based on the gaming medium state constituted by the first and second control state signals detected by the gaming medium state function described above. For example, if the maximum specified number of gaming media is "3", then if the gaming medium state is "00B" (when the medal counter value is "0"), it is determined to be invalid, and if it is any other gaming medium state, it is determined to be valid.

When the main CPU 501 determines in S1060 that the judgment condition of S1060 is not met (if S1060 is judged as NO), the main CPU 501 ends the game start preparation process and transfers the process to S1005 of the main flow (see FIG. 57).

On the other hand, in S1060, when the main CPU 501 determines that the determination condition of S1060 is satisfied (if S1060 is a YES determination), the main CPU 501 performs a transmission registration process of a medal insertion request command for the insertion count of "1" to be transmitted to the medal count control board 443 (S1061). Note that the medal insertion request command registered (saved) in this process in a communication data storage area (not shown) in the main RAM 503 (for medal count control transmission) is transmitted from the main control board 441 to the medal count control board 443 in a medal count control transmission process in a fixed cycle interrupt process (1.1172 msec cycle) described in FIG. 65 below.

Next, the main CPU 501 performs a response waiting process (S1062). In this process, the main CPU 501 transmits a medal insertion request command to the medal count control board 443, and waits until there is some kind of response from the medal count control board 443 to that command. The reception process (monitoring) of the response from the medal count control board 443 is performed by a reception interrupt process (irregularly) that will be described later in FIG. 67. In addition, when an Ack command is received in response to the medal insertion request command from the medal count control board 443, the main CPU 501 sets the insertion number (the value of the insertion counter) added to the Ack command to the number of game media inserted that is managed by the main control board 441.

Next, the main CPU 501 determines whether or not an Ack command has been received from the medal count control board 443 (S1063).

When the main CPU 501 determines in S1063 that it has not received an Ack command (if S1063 is a NO judgment), it returns the process to S1061 (the process of registering the transmission of the medal insertion request command) and repeats the process from S1061 onwards. On the other hand, when the main CPU 501 determines in S1063 that it has received an Ack command (if S1063 is a YES judgment), it ends the game start preparation process and moves the process to the process of S1005 of the main flow (see FIG. 57).

[10-17-5. Medal return process]
Next, the medal return process performed in S1005 of the main flow (see FIG. 57) will be described with reference to Fig. 61. Fig. 61 is a flow chart showing the procedure of the medal return process.

First, the main CPU 501 determines whether the return button 420 has been pressed and the current number of game media inserted is greater than "0" (hereinafter simply referred to as the "judgment condition of S1071") (S1071). Note that whether the return button 420 has been pressed or not is determined based on the on/off state of the return switch 420S, and if the return switch 420S is in the on state, it is determined that the return button 420 has been pressed.

When the main CPU 501 determines in S1071 that the judgment condition of S1071 is not met (if S1071 is a NO judgment), the main CPU 501 ends the medal return process and transfers the process to S1006 of the main flow (see FIG. 57).

On the other hand, in S1071, when the main CPU 501 determines that the determination condition of S1071 is satisfied (if S1071 is a YES determination), the main CPU 501 performs a process of registering the transmission of a medal return request command to be transmitted to the medal count control board 443 (S1072). In this embodiment, the medal return request command is set with command type information and the number of inserted gaming media that have been bet (return number: subsequent data). Note that the medal return request command registered (saved) in a communication data storage area (not shown) in the main RAM 503 (for medal count control transmission) in this process is transmitted from the main control board 441 to the medal count control board 443 in a medal count control transmission process in a fixed cycle interrupt process (1.1172 msec cycle) described in FIG. 65 below.

Then, the main CPU 501 performs a response waiting process (S1073). In this process, the main CPU 501 transmits a medal return request command to the medal count control board 443, and waits until there is some kind of response from the medal count control board 443 to that command. Note that the reception process (monitoring) of the response from the medal count control board 443 is performed by a reception interrupt process (irregularly) that will be described later in FIG. 67.

Next, the main CPU 501 determines whether or not an Ack command has been received from the medal count control board 443 (S1074).

When the main CPU 501 determines in S1074 that it has not received an Ack command (if S1074 is a NO determination), it returns the process to S1072 (the medal return request command transmission registration process) and repeats the process from S1072 onwards. On the other hand, when the main CPU 501 determines in S1074 that it has received an Ack command (if S1074 is a YES determination), it ends the medal return process and moves the process to S1006 of the main flow (see FIG. 57).

[10-17-6. Game start processing]
Next, the game start processing performed in S1006 in the main flow (see FIG. 57) will be described with reference to Fig. 62. Note that Fig. 62 is a flow chart showing the procedure of the game start processing.

First, the main CPU 501 determines whether the VL signal (connection signal) is in the ON state (S1081).

When the main CPU 501 determines in S1081 that the VL signal is not on (if S1081 is a NO determination), the main CPU 501 ends the game start process and moves the process to S1007 of the main flow (see FIG. 57). In other words, if the VL signal is not on when the game starts (if a situation occurs in which the connection to the game media lending device 402 cannot be confirmed), the game does not start.

On the other hand, when the main CPU 501 determines in S1081 that the VL signal is in the ON state (if S1081 returns a YES determination), the main CPU 501 determines whether the number of gaming media inserted is the maximum specified number ("3") (S1082).

When the main CPU 501 determines in S1082 that the number of gaming media inserted is not the maximum specified number (if S1082 returns a NO judgment), the main CPU 501 ends the game start process and transfers the process to S1007 of the main flow (see FIG. 57).

On the other hand, when the main CPU 501 determines in S1082 that the number of game media inserted is the maximum specified number (if S1082 is a YES determination), the main CPU 501 determines whether the start lever 422 has been pressed (S1083). Note that whether the start lever 422 has been pressed is determined based on the on/off state of the start switch 422S, and if the start switch 422S is in the on state, it is determined that the start lever 422 has been pressed.

When the main CPU 501 determines in S1083 that the start lever 422 has not been pressed (if S1083 returns a NO judgment), the main CPU 501 ends the game start process and transfers the process to S1007 of the main flow (see FIG. 57).

On the other hand, when the main CPU 501 determines in S1083 that the start lever 422 has been pressed (if S1083 is a YES determination), the main CPU 501 performs a transmission registration process for a game start request command to be transmitted to the medal count control board 443 (S1084). In this embodiment, command type information and information on the RT state (subsequent data) are set in the game start request command. The game start request command registered (saved) in a communication data storage area (not shown) in the main RAM 503 (for medal count control transmission) in this process is transmitted from the main control board 441 to the medal count control board 443 in a medal count control transmission process in a fixed cycle interrupt process (1.1172 msec cycle) described in FIG. 65 below.

Then, the main CPU 501 performs a response waiting process (S1085). In this process, the main CPU 501 transmits a game start request command to the medal count control board 443, and waits until there is some kind of response from the medal count control board 443 to that command. Note that the reception process (monitoring) of the response from the medal count control board 443 is performed by a reception interrupt process (irregularly) that will be described later in FIG. 67.

Next, the main CPU 501 determines whether or not an Ack command has been received from the medal count control board 443 (medal count control CPU 501) (S1086).

When the main CPU 501 determines in S1086 that it has not received an Ack command (if S1086 is a NO judgment), it returns the process to S1084 (the game start request command transmission registration process) and repeats the process from S1084 onwards. On the other hand, when the main CPU 501 determines in S1086 that it has received an Ack command (if S1086 is a YES judgment), it ends the game start process and moves the process to the process of S1007 of the main flow (see FIG. 57).

[10-17-7. Game End Processing]
Next, the game ending process performed in S1009 in the main flow (see FIG. 57) will be described with reference to Fig. 63. Fig. 63 is a flow chart showing the procedure of the game ending process.

First, the main CPU 501 determines whether or not it has detected the off-edge of the stop button (stop switch) corresponding to the third stopped reel (whether or not the player's finger has been released from any of the stop buttons 423L, 423C, 423R corresponding to the third stopped reel) (S1091). When the main CPU 501 determines in S1091 that it has not detected the off-edge of the stop button corresponding to the third stopped reel (if S1091 is a NO determination), the main CPU 501 repeats the determination process of S1091.

On the other hand, when the main CPU 501 determines in S1091 that it has detected the off-edge of the stop button corresponding to the third stopped reel (if S1091 returns YES), the main CPU 501 performs a winning determination process (S1092). In this process, the main CPU 501 identifies the winning combination and determines the number of gaming media to be paid out, etc., based on the winning combination.

Next, the main CPU 501 performs a game state update process (S1093). In this process, the main CPU 501 performs a process of maintaining or transitioning the game state and RT state for the next game and thereafter, based on the internal winning combination and established combination determined in the game, the current game state and RT state, etc.

Next, the main CPU 501 performs a transmission registration process for the game end request command to be transmitted to the medal count control board 443 (S1094). In this embodiment, command type information and information on the game status (subsequent data) are set in the game end request command. Note that the game end request command registered (saved) in this process in a communication data storage area (for medal count control transmission) not shown in the main RAM 503 is transmitted from the main control board 441 to the medal count control board 443 in a medal count control transmission process within a fixed-cycle interrupt process (1.1172 msec cycle) described in FIG. 65 below.

Then, the main CPU 501 performs a response waiting process (S1095). In this process, the main CPU 501 transmits a game end request command to the medal count control board 443, and waits until there is some kind of response from the medal count control board 443 to that command. Note that the reception process (monitoring) of the response from the medal count control board 443 is performed by a reception interrupt process (irregularly) that will be described later in FIG. 67.

Next, the main CPU 501 determines whether or not an Ack command has been received from the medal count control board 443 (S1096).

When the main CPU 501 determines in S1096 that it has not received an Ack command (if S1096 is a NO judgment), it returns the process to S1094 (the game end request command transmission registration process) and repeats the process from S1094 onwards. On the other hand, when the main CPU 501 determines in S1096 that it has received an Ack command (if S1096 is a YES judgment), it ends the game end process and moves the process to S1010 of the main flow (see FIG. 57).

[10-17-8. Gaming medal payout process]
Next, the medal payout process performed in S1010 of the main flow (see FIG. 57) will be described with reference to Fig. 64. Fig. 64 is a flow chart showing the procedure of the medal payout process.

First, the main CPU 501 performs a transmission registration process for a medal payout request command to be sent to the medal count control board 443 (S1101). In this embodiment, command type information and information on the number of medals to be paid out ("0": subsequent data when no medals are paid out) are set in the medal payout request command. Note that the medal payout request command registered (saved) in this process in a communication data storage area (for medal count control transmission) not shown in the figure in the main RAM 503 is transmitted from the main control board 441 to the medal count control board 443 in a medal count control transmission process in a fixed-cycle interrupt process (1.1172 msec cycle) described in FIG. 65 below.

Then, the main CPU 501 performs a response waiting process (S1102). In this process, the main CPU 501 transmits a medal payout request command to the medal count control board 443, and waits until there is some kind of response from the medal count control board 443 to that command. Note that the reception process (monitoring) of the response from the medal count control board 443 is performed by a reception interrupt process (irregularly) that will be described later in FIG. 67.

Then, the main CPU 501 judges whether or not an Ack command has been received from the medal count control board 443 (S1103). When the main CPU 501 judges in S1103 that an Ack command has been received (if S1103 is judged as YES), the main CPU 501 ends the game medal payout process and moves the process to S1004 of the main flow (see FIG. 57).

On the other hand, when the main CPU 501 determines in S1103 that it has not received an Ack command (if S1103 is a NO determination), the main CPU 501 determines whether an upper limit exceeding error has occurred (S1104). In the slot machine 401, when the payout number is added to the medal counter value managed by the medal count control board 443, if the added value exceeds the above-mentioned first upper limit value ("16369" in the slot machine 401, the first threshold value), the payout number is not added to the medal counter value, and a Nack command with an upper limit exceeding error code is sent from the medal count control board 443 to the main control board 441 as a response to the medal payout request command. Then, in the process of S1104, if the main CPU 501 receives a Nack command and an upper limit exceeding error code (subsequent data) is added to the received command, it determines that an upper limit exceeding error has occurred and the determination process of S1104 is YES; otherwise, if the Ack command cannot be received, the determination process of S1104 is NO.

When the main CPU 501 determines in S1104 that an upper limit exceeding error has occurred (if S1104 returns a YES determination), the main CPU 501 performs specific error processing corresponding to the upper limit exceeding error (S1105).

The specific error processing (excess error registration) of S1105 is as follows. First, the main CPU 501 performs error display processing using the two-digit seven-segment LED for payout display of the game information display unit 426a, and transmission registration processing (generation and storage processing) of an error command (including information indicating the occurrence of an upper limit exceeding error) to be sent to the sub-control board 442. Next, the main CPU 501 waits until the game medium status (two-bit data consisting of the first and second control status signals) input by the above-mentioned game medium status function from the medal count control board 443 to the main control board 441 via GPIO becomes "00B" (until the payout of the reserved number of game media is completed), and when the game medium status becomes "00B", it determines that the error has been cleared. Then, the main CPU 501 cancels the error display by the two-digit seven-segment LED for payout display of the game information display unit 426a, returns the display contents to those before the error occurred, performs a transmission registration process (generation and storage process) of the error command (including information indicating the cancellation of the occurring error) to be transmitted to the sub-control board 442, and ends the error processing. Note that the error command registered (saved) in the communication data storage area (for sub-control transmission) not shown in the main RAM 503 in this error processing is transmitted from the main control board 441 to the sub-control board 442 in a sub-control transmission process in a fixed-period interrupt process (1.1172 msec period) described later in FIG. 65. Also, in this embodiment, the progress of the game is stopped until the game medium state becomes "00B", that is, until the upper limit exceeding error is canceled, and when the game medium state becomes "00B", the upper limit exceeding error is canceled and the game is resumed.

Then, after processing S1105, the main CPU 501 returns the process to S1101 (the process of registering the sending of a medal payout request command) and repeats the process from S1101 onwards.

On the other hand, when the main CPU 501 determines in S1104 that an upper limit exceeding error has not occurred (if S1104 is a NO determination), the main CPU 501 determines whether an upper limit exceeding notice error has occurred (S1106). In this embodiment, when the payout number is added to the value of the medal counter managed by the medal count control board 443, if the added value exceeds the second upper limit value (a value less than the first upper limit value: for example, "15000", the second threshold value), the payout number is added to the medal counter value, but a Nack command with an upper limit exceeding notice error code added is sent from the medal count control board 443 to the main control board 441 as a response to the medal payout request command. Then, in the process of S1106, if the main CPU 501 receives a Nack command and an upper limit exceeded warning error code (subsequent data) is added to the received command, it determines that an upper limit exceeded warning error has occurred, and the determination process of S1106 is YES; otherwise, if the Ack command cannot be received, the determination process of S1106 is NO.

When the main CPU 501 determines in S1106 that an upper limit exceeding warning error has not occurred (if S1106 is a NO determination), the main CPU 501 returns the process to S1101 (the process of registering the sending of a medal payout request command) and repeats the processes from S1101 onwards.

On the other hand, in S1106, when the main CPU 501 determines that an upper limit exceeding warning error has occurred (if S1106 returns a YES judgment), the main CPU 501 performs a predetermined error process corresponding to the upper limit exceeding warning error (S1107).

In the predetermined error processing (excess notice error registration) of S1107, the main CPU 501 performs a transmission registration process (generation and storage process) of an error command (including information indicating the occurrence of an upper limit exceeding notice error) to be transmitted to the sub-control board 442. The error command registered (saved) in the communication data storage area (for sub-control transmission) not shown in the main RAM 503 in this process is transmitted from the main control board 441 to the sub-control board 442 in the sub-control transmission process in the fixed-period interrupt process (1.1172 msec period) described later in FIG. 65. In addition, in this embodiment, if an upper limit exceeding notice error occurs, the progress of the game is not stopped. Note that, if an upper limit exceeding notice error occurs, the main CPU 501 may perform an error display process using a two-digit 7-segment LED for payout display of the game information display unit 426a to notify the occurrence of the error. In this case, the sub-control board 442 that received the error command (including information indicating the occurrence of an upper limit exceeded warning error) will either interrupt the performance in progress and issue a normal error notification, or will maintain the performance in progress and notify the user that an upper limit exceeded warning error has occurred. In the latter case, for example, a message urging payment will be displayed in the upper right corner of the display screen of the display device 413 so as not to disrupt the performance in progress.

Then, after processing S1107, the main CPU 501 ends the game medal payout process and transfers the process to processing S1004 of the main flow (see FIG. 57).

[10-17-9. Periodic interrupt processing (1.1172 msec) controlled by the main CPU]
Next, the fixed-period interrupt processing performed by the main CPU 501 at a cycle of 1.1172 msec will be described with reference to Fig. 65. Fig. 65 is a flow chart showing the procedure of the fixed-period interrupt processing performed by the main CPU 501.

This interrupt process, which is executed repeatedly at a cycle of 1.1172 msec, is executed when an interrupt request signal from the interrupt controller 512 is input to the main CPU 501, which is generated based on the output timing of the timeout signal of the timer circuit 513 set in the initialization process of the timer circuit 513 (PTC) (see S1021 in FIG. 58).

First, the main CPU 501 performs port input/output processing (S1111). In this processing, port input processing is performed for the input ports connected to the outside of the main control board 441 (the medal count control board 443, various switches, etc.), and port output processing is performed for the output ports.

Next, the main CPU 501 performs reel control processing (S1112). In this processing, when a request is made to start spinning all reels, the main CPU 501 starts the rotation of the left reel 412L, the center reel 412C, and the right reel 412R, and then drives and controls the three stepping motors so that each reel rotates at a constant speed. Also, when the number of sliding pieces is determined, the main CPU 501 updates the symbol counter of the corresponding reel by the number of sliding pieces. Then, the main CPU 501 waits until the updated symbol counter matches the value corresponding to the planned stop position (the symbol at the planned stop position reaches the area on the pay line in the display window), and then drives and controls the corresponding stepping motor so that the rotation of the corresponding reel is decelerated and stopped.

Next, the main CPU 501 performs a medal count clear check process (S1113). In this process, the main CPU 501 performs a transmission registration process of a clear check request command to be sent to the medal count control board 443, a check process of whether the medal count clear switch 443a is pressed when the power is turned on, a transmission registration process of a command to be sent to the sub-control board 442 at the start and end of the medal count clear process, and the like. In this embodiment, the medal count clear check process is not performed in the main flow (see FIG. 57), but is performed by the main CPU 501 in a fixed-period interrupt process. This is because if the medal count clear check process is performed in the main flow when the power is turned on (for example, if it is performed in the power-on process (S1001)), there is a possibility that the setting change process (S1003 in FIG. 57) cannot be performed, that is, the setting change process and the medal count clear check process cannot be performed simultaneously. Details of the medal count clear check process will be described later with reference to FIG. 66.

Next, the main CPU 501 performs a sub-control transmission process (a process of transmitting communication data to the sub-control board 442) (S1114). In this process, the main CPU 501 transmits various commands stored in a communication data storage area (for sub-control transmission) not shown in the main RAM 503 to the sub-control board 442 via one of the communication circuits SCU1 to 3 in the serial communication circuit 514 (see FIG. 43). After transmitting a command to the sub-control board 442, the main CPU 501 subtracts one packet from the communication data pointer (not shown) and clears the transmitted command data in the communication data storage area (for sub-control transmission). If multiple command data are stored in the communication data storage area (for sub-control transmission), the main CPU 501 transmits the command data to the sub-control board 442 in the order of oldest to newest. If no command data is stored in the communication data storage area (for sub-control transmission), the main CPU 501 generates a no-operation command and transmits it to the sub-control board 442.

When a no-operation command is generated, the port I/O process adds the state of the input port that is input from the input port and the state of the output port that is output from the output port to generate the no-operation command data.

Next, the main CPU 501 performs medal count control transmission processing (communication data transmission processing to the medal count control board 443) (S1115). In this processing, the main CPU 501 transmits various commands stored in a communication data storage area (not shown) in the main RAM 503 (for medal count control transmission) to the medal count control board 443 via the communication circuit SCU0 (see FIG. 43) in the serial communication circuit 514. In addition, after transmitting the command to the medal count control board 443, the main CPU 501 updates the communication data pointer by subtracting one packet (not shown) and clears the transmitted command data in the communication data storage area (for medal count control transmission).

Next, the main CPU 501 performs 7-segment LED drive processing (S1116). In this processing, the main CPU 501 controls the drive of various 7-segment LEDs provided in the pachislot 401. For example, the main CPU 501 controls the operation of the 7-segment LEDs of the game information display unit 426a and line LEDs such as "START", the 7-segment LEDs that display the number of game media paid out, the number of game media stored, the number of game media inserted, the order in which the stop buttons are pressed, and the 4-digit 7-segment LEDs that make up the winning combination monitor 454.

Then, the main CPU 501 performs a timer update process (S1117). In this process, the main CPU 501 performs a count (subtraction) process for the various timers that have been set. Then, after processing S1117, the main CPU 501 ends the fixed-period interrupt process.

[10-17-10. Medal count clear check process]
Next, with reference to Fig. 66, a description will be given of the medal count clear check process performed in S1113 during the periodic interrupt process (see Fig. 65) performed by the main CPU 501. Note that Fig. 66 is a flow chart showing the procedure of the medal count clear check process.

First, the main CPU 501 determines whether or not the medal count clear check has been completed (S1121). In this process, the main CPU 501 refers to medal count clear check completed information (e.g., a flag or parameter) indicating that the medal count clear switch 443a mounted on the medal count control board 443 was pressed when the power was turned on. Note that in the pachislot 401, medal count clear check completed is set when the medal count clear switch 443a is pressed when the power is turned on and the medal count clear process is completed, and when the medal count clear switch 443a is not pressed when the power is turned on (when the machine is started without pressing the medal count clear switch 443a) (see S1131 described below).

When the main CPU 501 determines in S1121 that the medal count clear check has been performed (if S1121 returns a YES determination), the main CPU 501 ends the medal count clear check process and transfers processing to S1114 of the periodic interrupt process (see FIG. 65).

On the other hand, when the main CPU 501 determines in S1121 that the medal count clear check has not been completed (if S1121 is a NO determination), the main CPU 501 determines whether or not the reply waiting flag is ON (S1122). The reply waiting flag is a flag that indicates whether or not the main control board 441 is waiting to receive a response signal (reply) from the medal count control board 443 in response to the clear check request command sent to the medal count control board 443. When the main control board 441 is waiting to receive a response signal from the medal count control board 443 in response to the clear check request command, the reply waiting flag is set to ON, and when the response signal is received by the main control board 441, the reply waiting flag is set to OFF.

When the main CPU 501 determines in S1122 that the reply waiting flag is on (if S1122 returns a YES determination), the main CPU 501 performs the processing of S1125, which will be described later.

On the other hand, when the main CPU 501 determines in S1122 that the reply waiting flag is not on (if S1122 is a NO determination), the main CPU 501 performs a transmission registration process (generation and storage process) of the clear check request command to be transmitted to the medal count control board 443 (S1123). Note that the clear check request command registered (saved) in this process in a communication data storage area (not shown) in the main RAM 503 (for medal count control transmission) is transmitted from the main control board 441 to the medal count control board 443 in the medal count control transmission process (S1115) in the fixed cycle interrupt process (1.1172 msec cycle) described in FIG. 65.

Next, the main CPU 501 sets the reply waiting flag to the ON state (S1124). The reply waiting flag is stored in a specified storage area in the main RAM 503. After processing S1124, the main CPU 501 ends the medal count clear check process and moves the process to S1114 of the periodic interrupt process (see FIG. 65).

If S1122 is a YES judgment, the main CPU 501 judges whether or not an Ack command has been received from the medal count control board 443 (S1125). If the main CPU 501 judges in S1125 that an Ack command has not been received (if S1125 is a NO judgment), the main CPU 501 returns the process to S1123 and performs the process from S1123 onwards.

On the other hand, when the main CPU 501 determines in S1125 that an Ack command has been received (if S1125 is a YES determination), the main CPU 501 determines whether or not it is time to start clearing the number of medals (reserved number) (S1126). This determination is made based on the subsequent data (parameters) added to the received Ack command (a response to the clear check request command).

A parameter indicating the state of the medal count clear switch 443a is added to the Ack command returned from the medal count control board 443 in response to the clear check request command. If the medal count clear switch 443a is pressed and in the on state when the power is turned on, a parameter indicating the start of clearing (in this embodiment, "1") is added to the Ack command. Also, if the medal count clear switch 443a is pressed and the medal counter value (accumulated number) is cleared, and then the medal count clear switch 443a is in the off state, a parameter indicating the end of clearing (in this embodiment, "2") is added to the Ack command. Note that if the medal count clear switch 443a is in the off state when the power is turned on (when the medal count clear switch 443a is started without being pressed), a parameter indicating that the medal count clear switch 443a is not pressed (in this embodiment, "0") is added to the Ack command. Therefore, the main CPU 501 can determine whether the medal count clear switch 443a was pressed when the power was turned on by referring to the parameters added to the Ack command returned from the medal count control board 443 in response to the clear check request command.

When the main CPU 501 determines in S1126 that clearing of the number of medals has not started (if S1126 returns NO), the main CPU 501 performs the process of S1129 described below.

On the other hand, when the main CPU 501 determines in S1126 that it is time to start clearing the medal count (if S1126 is a YES determination: the parameter added to the Ack command = "1"), the main CPU 501 performs a transmission registration process (generation and storage process) of a medal count clear start command (predetermined information) to be transmitted to the sub-control board 442 (S1127). Note that the medal count clear start command registered (saved) in a communication data storage area (not shown) in the main RAM 503 (for sub-control transmission) in this process is transmitted from the main control board 441 to the sub-control board 442 in a sub-control transmission process (S1114) in the fixed-cycle interrupt process (1.1172 msec cycle) described in FIG. 65.

Next, the main CPU 501 sets the reply waiting flag to the OFF state (S1128). After processing S1128, the main CPU 501 ends the medal count clear check process and transfers the process to S1114 of the periodic interrupt process (see FIG. 65).

If S1126 is judged as NO, the main CPU 501 judges whether or not the clearing of the number of medals (reserved number) has been completed (S1129). This judgment is made based on the parameters (subsequent data) added to the received Ack command (reply to the clear check request command).

When the main CPU 501 determines in S1129 that the medal count has not been cleared (if S1129 is a NO determination: the parameter added to the Ack command = "0"), the main CPU 501 performs the process of S1131 described below.

On the other hand, when the main CPU 501 determines in S1129 that the medal count clearing has been completed (if S1129 is a YES determination: the parameter added to the Ack command = "2"), the main CPU 501 performs a transmission registration process (generation and storage process) of a medal count clearing completion command (specific information) to be transmitted to the sub-control board 442 (S1130). Note that the medal count clearing completion command registered (saved) in a communication data storage area (not shown) in the main RAM 503 (for sub-control transmission) in this process is transmitted from the main control board 441 to the sub-control board 442 in a sub-control transmission process (S1114) in the fixed-cycle interrupt process (1.1172 msec cycle) described in FIG. 65.

After processing S1130, or if S1129 is judged as NO, the main CPU 501 sets the medal count clear check completed (S1131). Specifically, the main CPU 501 saves (stores) information indicating that the medal count clear check has been completed (e.g., a flag or parameter) in a specified storage area in the main RAM 503. Note that the process of clearing the information indicating that the medal count clear check has been completed is performed in the initialization process of S1021 during the power-on process shown in FIG. 58. Then, after processing S1131, the main CPU 501 ends the medal count clear check process, and moves the process to S1114 of the fixed-period interrupt process (see FIG. 65).

[10-17-11. Reception interrupt processing under control of the main CPU]
Next, referring to Fig. 67, a reception interrupt process performed by the main CPU 501 when command data is received (irregularly) from the medal count control board 443 via the communication circuit SCU0 (see Fig. 43) in the serial communication circuit 514 will be described. Fig. 67 is a flow chart showing the procedure of the reception interrupt process performed by the main CPU 501.

First, the main CPU 501 stores the received data (e.g., subsequent data such as the number of coins inserted, an error code indicating an upper limit has been exceeded, etc.) added to the command data received from the medal count control board 443 in a received data storage area (not shown) provided in the main RAM 503 (S1141).

Next, the main CPU 501 stores the reception status of the command data received from the medal count control board 443 (status information indicating whether the received command data contains an abnormality such as a parity error or a framing error) in a reception status storage area (not shown) provided in the main RAM 503 (S1142). Then, after processing S1142, the main CPU 501 ends the reception interrupt processing.

[10-18. Explanation of the operation of the medal count control board (microprocessor for controlling medal count)]
Next, referring to Figures 68 to 81, the contents of various processes executed by the medal count control CPU 501 (CPU 501 provided in the microprocessor MP described in Figure 43) of the medal count control board 443 (medal count control microprocessor 460) using a program will be described.

[10-18-1. Power-on processing (medal count control)]
First, the procedure of the power-on process (medal count control) performed by the medal count control CPU 501 will be described with reference to the flowchart shown in FIG. 68 (hereinafter referred to as the "medal count control flow").

First, the medal count control CPU 501 performs an initialization process (S1201). In this process, the medal count control CPU 501 initializes the medal count control CPU 501's device settings, etc. In this process, the timer circuit 513 and serial communication circuit 514 (SCU0 to 3) are also initialized.

Next, the medal count control CPU 501 performs medal count clear switch check processing (S1202). In this processing, the medal count control CPU 501 performs processing to check the state (on/off state) of the medal count clear switch 443a when the power is turned on, and processing to transmit and register an Ack command (a response to a clear check request command received from the main control board 441) to which information on the state is added. Details of the medal count clear switch check processing will be explained later with reference to FIG. 69.

Then, the medal count control CPU 501 performs a peripheral device connection confirmation process (S1203). In this process, the medal count control CPU 501 performs a process to confirm the connection state with the game media lending device 402 at the time of startup. Details of the peripheral device connection confirmation process will be explained later with reference to FIG. 70.

Then, the medal count control CPU 501 performs processing when a startup command is received (S1204). In this processing, the medal count control CPU 501 mainly receives the startup confirmation command sent from the main control board 441, and performs a transmission registration process of a response command (Ack command or Nack command) to that command. Details of the startup command reception processing will be explained later with reference to FIG. 71.

Then, the medal count control CPU 501 performs a peripheral device identification code transmission process (S1205). In this process, the medal count control CPU 501 performs a transmission and registration process of the chip individual number of the main control microprocessor 450 or the medal count control microprocessor 460 to be transmitted to the peripheral device (such as the game media lending device 402). Details of the peripheral device identification code transmission process will be explained later with reference to FIG. 72. Note that the above-mentioned processes of S1201 to S1205 are performed only once when the power is turned on.

Next, the medal count control CPU 501 performs processing when a setting change is received (S1206). In this processing, when the medal count control CPU 501 receives a setting change command (setting change start command or setting change end command) transmitted from the main control board 441, it mainly performs a transmission registration process of a response command (Ack command or Nack command) to the command. Details of the setting change reception processing will be explained later with reference to FIG. 73 described below.

Next, the medal count control CPU 501 performs processing when a medal insertion request command is received (S1207). In this processing, when the medal count control CPU 501 receives a medal insertion request command transmitted from the main control board 441, it mainly performs a transmission registration process of a response command (Ack command or Nack command) to the command. The medal insertion request command reception processing will be explained later with reference to FIG. 74.

Next, the medal count control CPU 501 performs processing when a medal return request command is received (S1208). In this processing, when the medal count control CPU 501 receives a medal return request command transmitted from the main control board 441, it mainly performs a transmission registration process of a response command (Ack command or Nack command) to the command. Note that the medal return request command reception processing will be explained later with reference to FIG. 75 below.

Next, the medal count control CPU 501 performs processing when a medal payout request command is received (S1209). In this processing, when the medal count control CPU 501 receives a medal payout request command transmitted from the main control board 441, it mainly performs a transmission registration process of a response command (Ack command or Nack command) to the command. Note that the medal payout request command reception processing will be explained later with reference to FIG. 76 below.

Then, the medal count control CPU 501 performs processing when the settlement switch is pressed (S1210). In this processing, the medal count control CPU 501 mainly performs a transmission and registration process of the number of game media to be paid out, which is transmitted to a peripheral device (such as the game media lending device 402). The processing when the settlement switch is pressed will be explained later with reference to FIG. 77 below.

Next, the medal count control CPU 501 performs processing when a medal lending instruction is received (S1211). In this processing, when the medal count control CPU 501 receives a medal lending instruction command (information on pressing the lending button 419) input from the game media lending device 402, it mainly performs a transmission registration process of a response command (Ack command or Nack command) to the command. The medal lending instruction reception processing will be explained later with reference to FIG. 78 described below.

Then, after processing S1211, the medal count control CPU 501 returns the process to S1206 (processing upon receiving setting change) and repeats the processes from S1206 onwards.

[10-18-2. Medal count clear switch check process (medal count control)]
Next, the medal count clear switch check process performed in S1202 in the medal count control flow (see FIG. 68) will be described with reference to Fig. 69. Note that Fig. 69 is a flow chart showing the procedure of the medal count clear switch check process.

First, the medal count control CPU 501 determines whether the medal count clear switch 443a is in the ON state (S1221). In this process, the medal count control CPU 501 determines the ON/OFF state of the medal count clear switch 443a based on the detection signal output from the medal count clear switch 443a.

When the medal count control CPU 501 determines in S1221 that the medal count clear switch 443a is not in the ON state (if S1221 returns a NO determination), the medal count control CPU 501 performs the processing of S1228 described below.

On the other hand, in S1221, when the medal count control CPU 501 determines that the medal count clear switch 443a is in the ON state (if S1221 is a YES judgment), the medal count control CPU 501 determines whether or not a clear check request command has been received from the main control board 441 (S1222). In S1222, when the medal count control CPU 501 determines that a clear check request command has not been received (if S1222 is a NO judgment), the medal count control CPU 501 repeats the processing of S1222.

On the other hand, in S1222, when the medal count control CPU 501 determines that a clear check request command has been received (if S1222 returns a YES judgment), the medal count control CPU 501 clears (to 0) the medal counter value (S1223).

Next, the medal count control CPU 501 performs a transmission registration process (generation and storage process) of an Ack command in response to the clear check request command (S1224). In this process, the medal count control CPU 501 adds (sets) a parameter ("1") indicating the start of clearing the medal counter to the Ack command. In addition, the Ack command registered (saved) in this process in a communication data storage area (not shown) in the medal count control RAM 503 (for main control transmission) is transmitted from the medal count control board 443 to the main control board 441 in a main control transmission process in a fixed-cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501.

Next, the medal count control CPU 501 determines whether the medal count clear switch 443a is in the OFF state (S1225). When the medal count control CPU 501 determines in S1225 that the medal count clear switch 443a is not in the OFF state (if S1225 returns a NO determination), the medal count control CPU 501 repeats the processing of S1225.

On the other hand, in S1225, when the medal count control CPU 501 determines that the medal count clear switch 443a is in the OFF state (if S1225 is a YES judgment), the medal count control CPU 501 determines whether or not a clear check request command has been received from the main control board 441 (S1226). In S1226, when the medal count control CPU 501 determines that a clear check request command has not been received (if S1226 is a NO judgment), the medal count control CPU 501 repeats the processing of S1226.

On the other hand, when the medal count control CPU 501 determines in S1226 that it has received a clear check request command (if S1226 is a YES determination), the medal count control CPU 501 performs a transmission registration process (generation and storage process) of an Ack command in response to the clear check request command (S1227). In this process, the medal count control CPU 501 adds (sets) a parameter ("2") indicating the completion of clearing the medal counter to the Ack command. In addition, the Ack command registered (saved) in the communication data storage area (not shown) in the medal count control RAM 503 in this process (for main control transmission) is transmitted from the medal count control board 443 to the main control board 441 in the main control transmission process in the fixed-cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501. Then, after processing S1227, the medal count control CPU 501 ends the medal count clear switch check process and transfers processing to S1203 in the medal count control flow (see FIG. 68).

Now, the process returns to S1221 again. If S1221 returns a NO judgment, the medal count control CPU 501 judges whether or not a clear check request command has been received from the main control board 441 (S1228). If, in S1228, the medal count control CPU 501 judges that a clear check request command has not been received (if S1228 returns a NO judgment), the medal count control CPU 501 repeats S1228.

On the other hand, when the medal count control CPU 501 determines in S1228 that it has received a clear check request command (if S1228 is a YES determination), the medal count control CPU 501 performs a transmission registration process (generation and storage process) of an Ack command for the clear check request command (S1229). In this process, the medal count control CPU 501 adds (sets) a parameter ("0") indicating that the medal count clear switch 443a was not pressed when the power was turned on to the Ack command. In addition, the Ack command registered (saved) in the communication data storage area (not shown) in the medal count control RAM 503 in this process (for main control transmission) is transmitted from the medal count control board 443 to the main control board 441 in the main control transmission process in the fixed-cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501. Then, after processing S1229, the medal count control CPU 501 ends the medal count clear switch check process and transfers processing to S1203 in the medal count control flow (see FIG. 68).

[10-18-3. Peripheral device connection confirmation process (medal count control)]
Next, the peripheral device connection confirmation process performed in S1203 in the medal count control flow (see FIG. 68) will be described with reference to Fig. 70. Note that Fig. 70 is a flow chart showing the procedure of the peripheral device connection confirmation process.

First, the medal count control CPU 501 sets the output port of the PRDY signal (STB signal) and the output port of the EXS signal (data signal) output from the medal count control board 443 to the game media lending device 402 to the ON state (S1231).

Next, the medal count control CPU 501 determines whether the input port for the BRDY signal (STB signal) or the input port for the BRQ signal (data signal) input from the game media lending device 402 to the medal count control board 443 is in the ON state (S1232).

In S1232, when the medal count control CPU 501 determines that the state of the monitored input port (BRDY signal input port or BRQ signal input port) is not in the ON state (if S1232 is a NO judgment), the medal count control CPU 501 repeats the judgment process of S1232 until the judgment process of S1232 becomes a YES judgment (until the state of the monitored input port becomes the ON state).

On the other hand, in S1232, when the medal count control CPU 501 determines that the state of the monitored input port (BRDY signal input port or BRQ signal input port) is on (if S1232 is a YES determination), the medal count control CPU 501 determines whether the on state of the monitored input port (BRDY signal input port or BRQ signal input port) is maintained for a predetermined period (200 msec or more) (S1233).

In S1233, when the medal count control CPU 501 determines that the on state of the monitored input port (the input port of the BRDY signal or the input port of the BRQ signal) has not been maintained for a predetermined period (if S1233 is a NO judgment), the medal count control CPU 501 repeats the judgment process of S1233 until the judgment process of S1233 becomes a YES judgment (until the on state of the monitored input port is maintained for a predetermined period).

On the other hand, in S1233, when the medal count control CPU 501 determines that the on state of the monitored input port (BRDY signal input port or BRQ signal input port) has been maintained for a predetermined period of time (if S1233 returns a YES determination), the medal count control CPU 501 ends the peripheral device connection confirmation process and transfers the medal count process to S1204 in the control flow (see FIG. 68).

As described above, in the gaming system 400 of this embodiment, if an abnormality occurs in the connection between the medal count control board 443 and the gaming medium lending device 402 for some reason at startup and the connection between the two cannot be confirmed or the connection between the two is unstable, the result of the judgment process of S1232 or S1233 will be a NO judgment, and the processing of S1232 or S1233 will be repeated. Therefore, if such a situation occurs, the processing after the peripheral device connection confirmation process (the processing after S1203 in FIG. 68) will not be performed, and game play will not start.

[10-18-4. Processing upon receiving start command (control of medal count)]
Next, the startup command reception process performed in S1204 in the medal count control flow (see FIG. 68) will be described with reference to Fig. 71. Note that Fig. 71 is a flow chart showing the procedure of the startup command reception process.

First, the medal count control CPU 501 performs a response waiting process (S1241). In this process, the medal count control CPU 501 waits until it receives data such as a command from the main control board 441. The reception process of data such as a command from the main control board 441 is performed by the medal count control CPU 501 in a main control reception interrupt process (irregularly: see FIG. 81 described below).

Next, the medal count control CPU 501 determines whether or not a startup confirmation command has been received (S1242).

When the medal count control CPU 501 determines in S1242 that it has not received the start confirmation command (if S1242 is a NO determination), the medal count control CPU 501 performs a transmission registration process for a Nack command (non-acknowledgement response command) (S1243). In this determination process, the case where the medal count control CPU 501 has received a command other than the start confirmation command, or a reception error (e.g., a parity error, a framing error, etc.) has occurred. In addition, the Nack command registered (saved) in the communication data storage area (not shown) in the medal count control RAM 503 in this process (for main control transmission) is transmitted from the medal count control board 443 to the main control board 441 in the main control transmission process in the fixed-cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501.

Then, after processing S1243, the medal count control CPU 501 returns the process to S1241 (response waiting process) and repeats the processes from S1241 onwards.

On the other hand, when the medal count control CPU 501 determines in S1242 that it has received the start confirmation command (if S1242 is a YES determination), the medal count control CPU 501 performs a process of registering the transmission of an Ack command (acknowledgement response command) (S1244). The Ack command registered (saved) in this process in a communication data storage area (not shown) in the medal count control RAM 503 (for main control transmission) is transmitted from the medal count control board 443 to the main control board 441 in a main control transmission process in a fixed-period interrupt process (1 msec period: see FIG. 79) executed by the medal count control CPU 501, which will be described later.

After processing S1244, the medal count control CPU 501 stores one byte of data (subsequent data) of the chip individual number of the main control microprocessor 450 that was added to the startup confirmation command in the main individual number storage area (not shown) in the medal count control RAM 503 (S1245).

Next, the medal count control CPU 501 determines whether reception of 4 bytes of data for the individual chip number (all data for the individual chip number) has been completed (S1246).

When the medal count control CPU 501 determines in S1246 that reception of 4 bytes of data for the individual chip number has not been completed (if S1246 is a NO judgment), the medal count control CPU 501 returns the process to S1241 (response waiting process) and repeats the process from S1241 onwards. On the other hand, when the medal count control CPU 501 determines in S1246 that reception of 4 bytes of data for the individual chip number has been completed (if S1246 is a YES judgment), the medal count control CPU 501 ends the process when the startup command is received and moves the process to S1205 of the medal count control flow (see FIG. 68).

[10-18-5. Peripheral device identification code transmission process (medal count control)]
Next, the peripheral device identification code transmission process performed in S1205 in the medal count control flow (see FIG. 68) will be described with reference to Fig. 72. Fig. 72 is a flow chart showing the procedure of the peripheral device identification code transmission process.

First, the medal count control CPU 501 stores the data (4 bytes) of the chip individual number of the medal count control microprocessor 460 stored in the unique information 509 in the payout individual number storage area (not shown) in the medal count control RAM 503 (S1251).

Next, the medal count control CPU 501 determines whether the chip individual number to be sent to the peripheral device is the chip individual number of the main control microprocessor 450 (S1252).

When the medal count control CPU 501 determines in S1252 that the chip individual number to be transmitted to the peripheral device is the chip individual number of the main control microprocessor 450 (if S1252 is a YES determination), the medal count control CPU 501 performs a transmission registration process of one byte of data constituting the chip individual number of the main control microprocessor 450 (S1253). Then, after processing S1253, the medal count control CPU 501 performs the process of S1255 described below.

On the other hand, in S1252, when the medal count control CPU 501 determines that the chip individual number to be transmitted to the peripheral device is not the chip individual number of the main control microprocessor 450 (if S1252 is a NO determination), the medal count control CPU 501 performs a transmission and registration process of one byte of data constituting the chip individual number of the medal count control microprocessor 460 (S1254). Note that in this embodiment, the data transmission process of one byte of the chip individual number is repeated four times, but the one byte of data registered for each transmission and registration process of S1253 or S1254 is set so that it does not overlap with each other.

After processing S1253 or S1254, the medal count control CPU 501 waits until the transmission process of 1 byte of data of the registered chip individual number is completed (S1255). Note that in the processing of S1253 or S1254, the data (1 byte of data of the chip individual number) registered (saved) in the communication data storage area (not shown) in the medal count control RAM 503 (for peripheral device transmission) is transmitted from the medal count control board 443 to the game media lending device 402 in the peripheral device transmission process in the fixed periodic interrupt process (1 msec period: see FIG. 79 described later) executed by the medal count control CPU 501.

Next, the medal count control CPU 501 determines whether transmission of 4 bytes of data for the individual chip number (all data for the individual chip number) has been completed (S1256).

When the medal count control CPU 501 determines in S1256 that the transmission of the four bytes of the chip individual number data has not been completed (if S1256 is a NO judgment), the medal count control CPU 501 returns the process to S1252 and repeats the process from S1252 onwards. On the other hand, when the medal count control CPU 501 determines in S1256 that the transmission of the four bytes of the chip individual number data has been completed (if S1256 is a YES judgment), the medal count control CPU 501 ends the peripheral device identification code transmission process and moves the process to S1206 of the medal count control flow (see FIG. 68).

Although not shown, information indicating whether the chip individual number of the main control microprocessor 450 or the chip individual number of the medal count control microprocessor 460 is to be sent to the peripheral device is stored in the medal count control ROM 502. Therefore, the chip individual number to be sent can be changed as desired depending on the specifications of the gaming system 400.

[10-18-6. Processing when receiving setting changes (control of medal count)]
Next, the process when a setting change is received, which is performed in S1206 in the medal count control flow (see FIG. 68), will be described with reference to Fig. 73. Fig. 73 is a flow chart showing the procedure of the process when a setting change is received.

First, the medal count control CPU 501 determines whether or not a setting change start command has been received from the main control board 441 (S1261). The reception process of the setting change start command from the main control board 441 is performed by the medal count control CPU 501 in the main control reception interrupt process (see FIG. 81 described below).

When the medal count control CPU 501 determines in S1261 that it has not received a setting change start command (if S1261 returns a NO determination), the medal count control CPU 501 ends the processing performed when a setting change is received, and transfers processing to S1207 of the medal count control flow (see FIG. 68).

On the other hand, when the medal count control CPU 501 determines in S1261 that it has received a setting change start command (if S1261 is a YES determination), the medal count control CPU 501 performs a transmission registration process of an Ack command (acknowledgement response command) to be transmitted to the main control board 441 (S1262). Note that the Ack command registered (saved) in this process in a communication data storage area (not shown) in the medal count control RAM 503 (for main control transmission) is transmitted from the medal count control board 443 to the main control board 441 in a main control transmission process in a fixed-cycle interrupt process (1 msec cycle: see FIG. 79) executed by the medal count control CPU 501, which will be described later.

Then, the medal count control CPU 501 performs a transmission registration process of the game information (start setting change) command to be transmitted to the game media lending device 402 (S1263). Note that the game information (start setting change) command (a command in which game information indicating the start of setting change is set) registered (saved) in this process in a communication data storage area (for peripheral device transmission) not shown in the medal count control RAM 503 is transmitted from the medal count control board 443 to the game media lending device 402 in a peripheral device transmission process in a fixed-period interrupt process (1 msec period: see FIG. 79 described later) executed by the medal count control CPU 501.

Then, the medal count control CPU 501 performs a response waiting process (S1264). In this process, the medal count control CPU 501 waits until it receives data such as a command from the main control board 441. Note that the reception process of data such as a command from the main control board 441 is performed by the medal count control CPU 501 in the main control reception interrupt process (see FIG. 81 described below).

Next, the medal count control CPU 501 determines whether or not a setting change end command has been received from the main control board 441 (S1265).

When the medal count control CPU 501 determines in S1265 that it has not received the setting change end command (if S1265 is a NO determination), the medal count control CPU 501 performs a transmission registration process of a Nack command (non-acknowledge response command) to be transmitted to the main control board 441 (S1266). Note that the Nack command registered (saved) in this process in a communication data storage area (for main control transmission) not shown in the medal count control RAM 503 is transmitted from the medal count control board 443 to the main control board 441 in a main control transmission process in a fixed cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501. Then, after processing S1266, the medal count control CPU 501 returns the process to S1264 (response waiting process) and repeats the processes from S1264 onwards.

On the other hand, when the medal count control CPU 501 determines in S1265 that it has received a setting change end command (if S1265 is a YES determination), the medal count control CPU 501 stores the setting information (subsequent data) added to the setting change end command in the medal count control RAM 503, and performs a transmission registration process of an Ack command (acknowledgement response command) to be transmitted to the main control board 441 (S1267). Note that the Ack command registered (stored) in a communication data storage area (not shown) in the medal count control RAM 503 (for main control transmission) in this process is transmitted from the medal count control board 443 to the main control board 441 in a main control transmission process in a fixed-cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501.

Then, the medal count control CPU 501 performs a transmission registration process of the game information (setting change end) command to be transmitted to the game media lending device 402 (S1268). Note that the game information (setting change end) command (a command in which game information indicating the setting change end is set) registered (saved) in this process in the communication data storage area (for peripheral device transmission) not shown in the medal count control RAM 503 is transmitted from the medal count control board 443 to the game media lending device 402 in the peripheral device transmission process in the fixed periodic interrupt process (1 msec period: see FIG. 79 described later) executed by the medal count control CPU 501.

Then, the medal count control CPU 501 performs an initialization process for the medal count control RAM 503 (S1269). Note that in the initialization process, the communication data storage area (for peripheral device transmission), communication data storage area (for main control transmission), and setting information (e.g., settings 1 to 6) of the medal count control RAM 503 are maintained without being initialized. Then, after processing S1269, the medal count control CPU 501 ends the processing when a setting change is received, and moves the process to S1207 of the medal count control flow (see FIG. 68).

[10-18-7. Processing upon receipt of medal insertion request command (medal count control)]
Next, the process performed in S1207 of the medal insertion request command reception in the medal count control flow (see FIG. 68) will be described with reference to Fig. 74. Fig. 74 is a flow chart showing the procedure of the process performed when a medal insertion request command is received.

First, the medal count control CPU 501 determines whether or not a medal insertion request command has been received from the main control board 441 (S1271). Note that the reception process of the medal insertion request command is performed by the medal count control CPU 501 in the main control reception interrupt process (see FIG. 81 described below).

When the medal count control CPU 501 determines in S1271 that a medal insertion request command has not been received (if S1271 returns a NO determination), the medal count control CPU 501 ends the processing performed when a medal insertion request command is received, and transfers processing to S1208 of the medal count control flow (see FIG. 68).

On the other hand, when the medal count control CPU 501 determines in S1271 that a medal insertion request command has been received (if S1271 returns a YES determination), the medal count control CPU 501 determines whether the medal counter value is greater than "0" (S1272).

When the medal count control CPU 501 determines in S1272 that the medal counter value is equal to or less than "0" (if S1272 returns a NO determination), the medal count control CPU 501 performs the processing of S1279, which will be described later.

On the other hand, when the medal count control CPU 501 determines in S1272 that the medal counter value is greater than "0" (if S1272 returns a YES determination), the medal count control CPU 501 subtracts 1 from the medal counter value (S1273). Next, the medal count control CPU 501 adds 1 to the insertion counter value (S1274).

Next, the medal count control CPU 501 determines whether the value of the insertion counter is greater than the maximum specified number of gaming media ("3") (S1275).

When the medal count control CPU 501 determines in S1275 that the value of the insertion counter is equal to or less than the maximum specified number (if S1275 returns NO), the medal count control CPU 501 performs the process of S1278, which will be described later.

On the other hand, when the medal count control CPU 501 determines in S1275 that the value of the insertion counter is greater than the maximum specified number (if S1275 returns a YES judgment), the medal count control CPU 501 sets the value of the insertion counter to "1" (S1276). Next, the medal count control CPU 501 adds a value obtained by subtracting 1 from the maximum specified number of game media ("3") to the medal counter value (S1277). That is, in this embodiment, when the value of the insertion counter becomes "4", the value of the insertion counter is set to "1" and "2" is added to the medal counter value.

After processing S1277, or if S1275 is judged as NO, the medal count control CPU 501 performs a transmission registration process of an Ack command (acknowledgement response command) to be transmitted to the main control board 441 (S1278). The Ack command registered (saved) in this process in a communication data storage area (for main control transmission) not shown in the medal count control RAM 503 is transmitted from the medal count control board 443 to the main control board 441 in a main control transmission process in a fixed cycle interrupt process (1 msec cycle: see FIG. 79) executed by the medal count control CPU 501. After processing S1278, the medal count control CPU 501 ends the process when receiving a medal insertion request command, and moves the process to S1208 of the medal count control flow (see FIG. 68).

Now, returning to the processing of S1272 again, if the judgment of S1272 is NO, the medal count control CPU 501 performs a transmission registration process of a Nack command (non-acknowledgement response command) to be transmitted to the main control board 441 (S1279). The Nack command registered (saved) in this process in a communication data storage area (for main control transmission) not shown in the figure in the medal count control RAM 503 is transmitted from the medal count control board 443 to the main control board 441 in the main control transmission process in the fixed cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501. Then, after the processing of S1279, the medal count control CPU 501 ends the process when receiving a medal insertion request command, and moves the process to the processing of S1208 in the medal count control flow (see FIG. 68).

Normally, the main control board 441 is configured such that when the medal counter value is "1" or greater, a medal insertion request command is sent to the medal count control board 443 (when the medal counter value is less than "1", a medal insertion request command is not sent to the medal count control board 443). Therefore, the processing route from a NO judgment at S1272 to the processing at S1279 is not a processing route that normally occurs, and this processing route (the processing of sending a Nack command) is a fail-safe process in the event that a failure occurs due to some kind of malfunction in the gaming system 400.

[10-18-8. Processing upon receipt of medal return request command (medal count control)]
Next, the process performed in S1208 of the medal count control flow (see FIG. 68) when a medal return request command is received will be described with reference to Fig. 75. Fig. 75 is a flow chart showing the procedure of the process performed when a medal return request command is received.

First, the medal count control CPU 501 determines whether or not a medal return request command has been received from the main control board 441 (S1281). Note that the medal return request command reception process is performed by the medal count control CPU 501 in the main control reception interrupt process (see FIG. 81, described below).

When the medal count control CPU 501 determines in S1281 that a medal return request command has not been received (if S1281 returns a NO determination), the medal count control CPU 501 ends the processing performed when a medal return request command is received, and transfers processing to S1209 of the medal count control flow (see FIG. 68).

On the other hand, in S1281, when the medal count control CPU 501 determines that a medal return request command has been received (if S1281 returns a YES judgment), the medal count control CPU 501 determines whether the medal counter value exceeds the medal counter's upper limit value ("16369") when the medal count control CPU 501 adds the subsequent data added to the medal return request command (number of game media returned = number inserted) to the medal counter value (S1282).

In S1282, when the medal count control CPU 501 determines that the medal counter value will exceed the medal counter's upper limit when the medal count (return count) is added to the medal counter value (if S1282 returns YES), the medal count control CPU 501 performs the processing of S1287 described below.

On the other hand, in S1282, when the medal count control CPU 501 determines that adding the number of medals inserted (number of medals returned) to the medal counter value does not exceed the medal counter's upper limit (below the upper limit) (if S1282 returns NO), the medal count control CPU 501 sets the subsequent data (number of medals inserted) in the insertion counter (S1283).

Then, the medal count control CPU 501 performs a transmission registration process of an Ack command (acknowledgement response command) to be transmitted to the main control board 441 (S1284). At this time, the medal count control CPU 501 adds the value of the insertion counter (= the number of game media returned) to the Ack command as subsequent data to the Ack command. The Ack command (+ the value of the insertion counter) registered (saved) in a communication data storage area (not shown) in the medal count control RAM 503 (for main control transmission) in this process is transmitted from the medal count control board 443 to the main control board 441 in a main control transmission process in a fixed-cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501, which will be described later.

Next, the medal count control CPU 501 adds the value of the insertion counter to the value of the medal counter (S1285). Next, the medal count control CPU 501 sets the value of the insertion counter to "0" (S1286). Then, after processing S1286, the medal count control CPU 501 ends the processing when a medal return request command is received, and moves the processing to processing S1209 of the medal count control flow (see FIG. 68).

Here, we return to the process of S1282 again. If S1282 is judged as YES, the medal count control CPU 501 performs a transmission registration process of a Nack command (non-acknowledgement response command) to be sent to the main control board 441 (S1287). At this time, the medal count control CPU 501 adds data indicating an upper limit exceedance error (upper limit exceedance error code) to the Nack command as subsequent data to the Nack command. Note that the Nack command (+upper limit exceedance error code) registered (saved) in the communication data storage area (for main control transmission) not shown in the figure in the medal count control RAM 503 in this process is transmitted from the medal count control board 443 to the main control board 441 in the main control transmission process in the fixed-cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501. Then, after processing S1287, the medal count control CPU 501 ends the processing when a medal return request command is received, and transfers processing to processing S1209 of the medal count control flow (see FIG. 68).

[10-18-9. Processing upon receipt of medal payout request command (medal count control)]
Next, the process executed in S1209 of the medal count control flow (see FIG. 68) when a medal payout request command is received will be described with reference to Fig. 76. Fig. 76 is a flow chart showing the procedure of the process executed when a medal payout request command is received.

First, the medal count control CPU 501 determines whether or not a medal payout request command has been received from the main control board 441 (S1291). The medal payout request command is received by the medal count control CPU 501 in the main control reception interrupt process (irregularly; see FIG. 81).

When the medal count control CPU 501 determines in S1291 that a medal payout request command has not been received (if S1291 returns a NO determination), the medal count control CPU 501 ends the processing performed when a medal payout request command is received, and transfers processing to S1210 of the medal count control flow (see FIG. 68).

On the other hand, in S1291, when the medal count control CPU 501 determines that a medal payout request command has been received (if S1291 returns a YES judgment), the medal count control CPU 501 determines whether the value of the medal counter exceeds the first upper limit value of the medal counter ("16369") when the subsequent data (number of payouts) added to the medal payout request command is added to the medal payout request command (S1292).

When the medal count control CPU 501 determines in S1292 that the medal counter value will exceed the first upper limit value of the medal counter when the payout number is added to the medal counter value (if S1292 returns a YES determination), the medal count control CPU 501 performs the processing of S1297 described below.

On the other hand, in S1292, when the medal count control CPU 501 determines that adding the payout number to the medal counter value will not exceed the first upper limit value of the medal counter (if S1292 returns a NO judgment), the medal count control CPU 501 adds the payout number (subsequent data) to the medal counter value (S1293).

Next, the medal count control CPU 501 determines whether the medal counter value plus the payout number exceeds the second upper limit value of the medal counter ("15,000") (S1294).

In S1294, when the medal count control CPU 501 determines that the value obtained by adding the payout number to the medal counter value does not exceed the second upper limit value of the medal counter (if S1294 is a NO determination), the medal count control CPU 501 performs a transmission registration process of an Ack command (acknowledgement response command) to be transmitted to the main control board 441 (S1295). At this time, the medal count control CPU 501 adds the payout number to the Ack command as subsequent data to the Ack command. The Ack command (+ payout number) registered (saved) in the communication data storage area (not shown) in the medal count control RAM 503 in this process (for main control transmission) is transmitted from the medal count control board 443 to the main control board 441 in the main control transmission process in the fixed cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501. Then, after processing S1295, the medal count control CPU 501 ends the processing when a medal payout request command is received, and transfers processing to processing S1210 of the medal count control flow (see FIG. 68).

On the other hand, in S1294, when the medal count control CPU 501 determines that the medal counter value plus the payout number exceeds the second medal counter upper limit (if S1294 returns a YES judgment), the medal count control CPU 501 sets the medal counter upper limit exceeded warning display (S1296). In this process, the medal count control CPU 501 sets the display data for notifying (displaying) a medal counter upper limit exceeded warning error on the one-digit seven-segment error display LED in the medal count display unit 426b.

Here, the process returns to S1292 again. If S1292 returns YES, the medal count control CPU 501 sets the medal counter upper limit exceeded display (S1297). In this process, the medal count control CPU 501 sets the display data for notifying (displaying) the medal counter upper limit exceeded error on the one-digit seven-segment LED for error display in the medal count display unit 426b.

Then, after processing S1296 or S1297, the medal count control CPU 501 performs a transmission registration process of a Nack command (non-acknowledge response command) to be sent to the main control board 441 (S1298). At this time, if the processing of S1298 is performed after the processing of S1296, the medal count control CPU 501 adds data indicating an upper limit exceeded warning error (upper limit exceeded warning error code) to the Nack command as the subsequent data of the Nack command. On the other hand, if the processing of S1298 is performed after the processing of S1297, the medal count control CPU 501 adds data indicating an upper limit exceeded error (upper limit exceeded error code) to the Nack command as the subsequent data of the Nack command. In addition, the Nack command (plus upper limit exceeded warning error code or upper limit exceeded error code) registered (saved) in this process in a communication data storage area (not shown) in the medal count control RAM 503 (for main control transmission) is transmitted from the medal count control board 443 to the main control board 441 in the main control transmission process in the fixed cycle interrupt process (1 msec cycle: see FIG. 79 below) executed by the medal count control CPU 501. After processing S1298, the medal count control CPU 501 ends the process when a medal payout request command is received, and moves the process to S1210 in the medal count control flow (see FIG. 68).

[10-18-10. Processing when settlement switch is pressed (control of medal count)]
Next, the process when the settlement switch is pressed, which is performed in S1210 in the medal count control flow (see FIG. 68), will be described with reference to Fig. 77. Fig. 77 is a flow chart showing the procedure of the process when the settlement switch is pressed.

First, the medal count control CPU 501 determines whether the settlement button 418 has been pressed (S1301). Whether the settlement button 418 has been pressed is determined based on the on/off state of the settlement switch 418S, and if the settlement switch 418S is in the on state, it is determined that the settlement button 418 has been pressed.

When the medal count control CPU 501 determines in S1301 that the settlement button 418 has not been pressed (if S1301 returns a NO judgment), the medal count control CPU 501 ends the processing performed when the settlement switch is pressed, and transfers processing to S1211 of the medal count control flow (see FIG. 68).

On the other hand, in S1301, when the medal count control CPU 501 determines that the settlement button 418 has been pressed (if S1301 is a YES determination), the medal count control CPU 501 performs a transmission registration process for a medal count (lower) instruction command (the lower 1 byte of the 2-byte data of the medal counter indicating the number of medals stored) to be transmitted to the game media lending device 402 (S1302). Note that the medal count (lower) instruction command registered (saved) in a communication data storage area (not shown) (for peripheral device transmission) in the medal count control RAM 503 in this process is transmitted from the medal count control board 443 to the game media lending device 402 in a peripheral device transmission process in a fixed-period interrupt process (1 msec period: see FIG. 79 described later) executed by the medal count control CPU 501, which will be described later.

Then, the medal count control CPU 501 performs a response waiting process (S1303). In this process, the medal count control CPU 501 transmits a medal count (lower) instruction command to the game media lending device 402, and waits until there is some kind of response from the game media lending device 402 to the command. Note that the process of receiving the response from the game media lending device 402 is performed in the peripheral device reception process within the fixed-period interrupt process (1 msec period: see FIG. 79 described later) executed by the medal count control CPU 501, which will be described later.

Next, the medal count control CPU 501 determines whether or not an Ack command (acknowledgement response command) has been received from the game media lending device 402 (S1304).

When the medal count control CPU 501 determines in S1304 that an Ack command has not been received (if S1304 returns a NO determination), the medal count control CPU 501 ends the processing performed when the settlement switch is pressed, and transfers processing to S1211 of the medal count control flow (see FIG. 68).

On the other hand, in S1304, when the medal count control CPU 501 determines that an Ack command has been received (if S1304 is a YES determination), the medal count control CPU 501 performs a transmission registration process of a medal count (upper) instruction command (the upper 1 byte of the 2-byte data of the medal counter indicating the number of medals stored) to be transmitted to the game media lending device 402 (S1305). Note that the medal count (upper) instruction command registered (saved) in the communication data storage area (for peripheral device transmission, not shown) in the medal count control RAM 503 in this process is transmitted from the medal count control board 443 to the game media lending device 402 in a peripheral device transmission process in a fixed-period interrupt process (1 msec period: see FIG. 79 described later) executed by the medal count control CPU 501, which will be described later.

Then, the medal count control CPU 501 performs a response waiting process (S1306). In this process, the medal count control CPU 501 transmits a medal count (higher order) instruction command to the game media lending device 402, and waits until there is some kind of response from the game media lending device 402 to the command. Note that the process of receiving the response from the game media lending device 402 is performed in the peripheral device reception process within the fixed-period interrupt process (1 msec period: see FIG. 79 described below) executed by the medal count control CPU 501, which will be described later.

Next, the medal count control CPU 501 determines whether or not an Ack command (acknowledgement response command) has been received from the game media lending device 402 (S1307).

When the medal count control CPU 501 determines in S1307 that an Ack command has not been received (if S1307 returns a NO determination), the medal count control CPU 501 ends the processing performed when the settlement switch is pressed, and transfers processing to S1211 of the medal count control flow (see FIG. 68).

On the other hand, in S1307, when the medal count control CPU 501 determines that an Ack command has been received (if S1307 is a YES determination), the medal count control CPU 501 performs a transmission registration process of a medal count completion command to be transmitted to the game media lending device 402 (S1308). Note that the medal count completion command registered (saved) in this process in a communication data storage area (not shown) in the medal count control RAM 503 (for peripheral device transmission) is transmitted from the medal count control board 443 to the game media lending device 402 in a peripheral device transmission process in a fixed-period interrupt process (1 msec period: see FIG. 79 described later) executed by the medal count control CPU 501.

Next, the medal count control CPU 501 sets the medal counter value to "0" (S1309). After processing S1309, the medal count control CPU 501 ends the settlement switch pressing process and transfers the process to S1211 of the medal count control flow (see FIG. 68).

In addition, in Pachislot 401, the upper limit of the medal counter, which is made up of 2 bytes, is set to "16369", which is "3FF1H" when converted to hexadecimal, and is within the numerical range of 2 bytes. Therefore, in this embodiment, even if the medal counter value exceeds the upper limit (all conditions that cause an upper limit exceeding error), it will not exceed the 2-byte range.

[10-18-11. Processing when medal lending command is received (medal count control)]
Next, the process when a medal lending instruction command is received, which is performed in S1211 in the medal count control flow (see FIG. 68), will be described with reference to Fig. 78. Note that Fig. 78 is a flow chart showing the procedure of the process when a medal lending instruction command is received.

First, the medal count control CPU 501 determines whether or not a medal lending instruction command has been received from the game media lending device 402 (S1311). The medal lending instruction command reception process is performed in the peripheral device reception process within the fixed-period interrupt process (1 msec period: see FIG. 79) executed by the medal count control CPU 501, which will be described later.

When the medal count control CPU 501 determines in S1311 that a medal lending instruction command has not been received (if S1311 returns a NO judgment), the medal count control CPU 501 ends the processing performed when a medal lending instruction command is received, and transfers processing to S1206 of the medal count control flow (see FIG. 68).

On the other hand, when the medal count control CPU 501 determines in S1311 that it has received a medal lending instruction command (if S1311 is a YES judgment), the medal count control CPU 501 determines whether or not it is possible to accept the instruction to lend a gaming medium (S1312). Note that in this judgment process, if the medal counter value is added with the number of loans (subsequent data added to the medal lending instruction command: for example, 50) and the value exceeds the medal counter's upper limit value ("16369") (if an upper limit exceeding error occurs), or if the setting is being changed, the setting is being confirmed, settlement is being made, a return is being made, a game is being played, or a payout is being made, it is not possible to accept (NO judgment); otherwise, it is possible to accept (YES judgment).

When the medal count control CPU 501 determines in S1312 that the instruction to lend a gaming medium can be accepted (if S1312 returns a YES determination), the medal count control CPU 501 adds the number of loans (subsequent data) to the medal counter value (S1313).

Next, the medal count control CPU 501 performs a transmission registration process of the Ack command to be sent to the game media lending device 402 (S1314). At this time, the medal count control CPU 501 adds data indicating the completion of the game medal lending to the Ack command as subsequent data to the Ack command. The Ack command (game medal lending completion) registered (saved) in the communication data storage area (for peripheral device transmission) not shown in the medal count control RAM 503 by this process is transmitted from the medal count control board 443 to the game media lending device 402 by the peripheral device transmission process in the fixed cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501. Then, after the process of S1314, the medal count control CPU 501 ends the process when receiving the medal lending instruction command and moves the process to the process of S1206 of the medal count control flow (see FIG. 68).

On the other hand, when the medal count control CPU 501 determines in S1312 that the instruction to lend a game medium cannot be accepted (if S1312 is a NO determination), the medal count control CPU 501 performs a transmission registration process of a Nack command to be transmitted to the game medium lending device 402 (S1315). The Nack command registered (saved) in the communication data storage area (not shown) in the medal count control RAM 503 (for peripheral device transmission) in this process is transmitted from the medal count control board 443 to the game medium lending device 402 in the peripheral device transmission process in the fixed cycle interrupt process (1 msec cycle: see FIG. 79 described later) executed by the medal count control CPU 501. Then, after the process of S1315, the medal count control CPU 501 ends the process when receiving the medal lending instruction command and moves the process to the process of S1206 in the medal count control flow (see FIG. 68).

[10-18-12. Fixed-period interrupt processing (1 msec) by control of medal count control CPU]
Next, the fixed-period interrupt processing performed by the medal count control CPU 501 at a cycle of 1 msec will be described with reference to Fig. 79. Fig. 79 is a flow chart showing the procedure of the fixed-period interrupt processing performed by the medal count control CPU 501. The fixed-period interrupt processing repeatedly performed at a cycle of 1 msec is a processing executed when an interrupt request signal from the interrupt controller 512 is input to the medal count control CPU 501, which is generated based on the output timing of the timeout signal of the timer circuit 513 set in the initialization process of the timer circuit 513 (PTC) (see S1201 in Fig. 68).

First, the medal count control CPU 501 performs port input processing (S1321). In this processing, port input processing is performed for input ports other than the input ports assigned to the BRDY signal (STB signal) and the BRQ signal (data signal) (for example, input ports assigned to the settlement switch 418S, the VL signal, etc.).

Then, the medal count control CPU 501 performs processing when game information is received (S1322). In this processing, the medal count control CPU 501 performs a transmission registration process of a response command (Ack or Nack command) to a command related to the game status received from the main control board 441, and a transmission registration process of a game information command to be transmitted to the game medium lending device 402. The processing when game information is received will be described later with reference to FIG. 80.

Next, the medal count control CPU 501 performs a main control transmission process (a process of transmitting communication data to the main control board 441) (S1323). In this process, the medal count control CPU 501 transmits various commands stored in the communication data storage area (for main control transmission) in the medal count control RAM 503 to the main control board 441 via the communication circuit SCU0 in the serial communication circuit 514 (see FIG. 43).

Then, the medal count control CPU 501 performs a peripheral device transmission process (a process of transmitting communication data to the game media lending device 402) (S1324). In this process, the medal count control CPU 501 outputs (transmits) various commands (data) stored in the communication data storage area (for peripheral device transmission) in the medal count control RAM 503 to the game media lending device 402 using GPIO.

Then, the medal count control CPU 501 performs peripheral device reception processing (S1325). In this processing, the medal count control CPU 501 performs input (reception) processing of various commands (data) output (transmitted) from the game media lending device 402 using the GPIO.

Next, the medal count control CPU 501 performs port output processing (S1326). In this processing, port output processing is performed for output ports other than the output ports assigned to the PRDY signal (STB signal) and the EXS signal (data signal). Note that the on/off control of the state of the first and second control status signals (control status signals output by the GPIO method from the medal count control board 443 to the main control board 441) controlled by the game medium status function is performed in this port output processing based on the value of the medal counter.

Then, the medal count control CPU 501 performs medal count display unit display processing (S1327). In this processing, the medal count control CPU 501 displays the medal counter value on the 5-digit 7-segment LED for credit display provided on the medal count display unit 426b, and displays an upper limit exceeded error, an upper limit exceeded warning error, and other errors detected by the medal count control board 443 on the 1-digit 7-segment LED for error display. Then, after processing S1327, the medal count control CPU 501 ends the fixed-period interrupt processing.

[10-18-13. Processing upon reception of gaming information (control of medal count)]
Next, with reference to Fig. 80, a description will be given of the game information reception process performed in S1322 during the periodic interrupt process (see Fig. 79) executed by the medal count control CPU 501. Fig. 80 is a flow chart showing the procedure of the game information reception process.

First, the medal count control CPU 501 determines whether or not a game start request command has been received from the main control board 441 (S1331).

When the medal count control CPU 501 determines in S1331 that it has received a game start request command (if S1331 is a YES determination), the medal count control CPU 501 performs a transmission registration process for the game information (game start) command to be transmitted to the game medium lending device 402 (S1332). Next, the medal count control CPU 501 performs a transmission registration process for the Ack command (acknowledgement response command) to be transmitted to the main control board 441 (S1333). Then, after processing S1333, the medal count control CPU 501 performs the processing of S1339 described below.

On the other hand, when the medal count control CPU 501 determines in S1331 that it has not received a game start request command (if S1331 returns a NO determination), the medal count control CPU 501 determines whether or not it has received a game end request command from the main control board 441 (S1334).

When the medal count control CPU 501 determines in S1334 that it has received a game end request command (if S1334 is a YES determination), the medal count control CPU 501 performs a transmission registration process for the game information (game end) command to be transmitted to the game medium lending device 402 (S1335). Next, the medal count control CPU 501 performs a transmission registration process for the Ack command (acknowledgement response command) to be transmitted to the main control board 441 (S1336). Then, after processing S1336, the medal count control CPU 501 performs the processing of S1339 described below.

On the other hand, when the medal count control CPU 501 determines in S1334 that it has not received a game end request command (if S1334 returns a NO determination), the medal count control CPU 501 determines whether it has received an out-of-range command or an error from the main control board 441 (S1337).

When the medal count control CPU 501 determines in S1337 that an out-of-range command or an error has not been received (if S1337 returns NO), the medal count control CPU 501 performs the processing of S1339, which will be described later.

On the other hand, in S1337, when the medal count control CPU 501 determines that an out-of-range command or an error has been received (if S1337 is determined to be YES), the medal count control CPU 501 performs a transmission registration process for a Nack command (non-acknowledge response command) to be sent to the main control board 441 (S1338).

Then, after processing S1333, S1336, or S1338, or if S1337 is judged as NO, the medal count control CPU 501 judges whether or not an out-of-range command has been received from the main control board 441 (S1339).

When the medal count control CPU 501 determines in S1339 that an out-of-range command has not been received (if S1339 returns a NO determination), the medal count control CPU 501 ends the processing upon reception of game information and transfers processing to S1323 of the periodic interrupt processing (see FIG. 79).

On the other hand, in S1339, when the medal count control CPU 501 determines that an out-of-range command has been received (if S1339 is a YES determination), the medal count control CPU 501 performs a transmission registration process for a Nack command (non-acknowledge response command) to be sent to the game medium lending device 402 (S1340). Then, after processing S1340, the medal count control CPU 501 ends the game information reception process and transfers processing to S1323 of the fixed-period interrupt process (see FIG. 79).

Note that the out-of-range command here has the following meaning. For example, in the case of a game start request command, "03H" is pre-assigned as the command type information, and other commands are also assigned command type information according to the command. Therefore, when a command is received in which a number other than this pre-assigned command type information is set as the command type information, that command becomes an out-of-range command. Therefore, the description (phrase) "command outside the assigned range of command type information" is an accurate description of an "out-of-range command."

[10-18-14. Main control reception interrupt processing by control of medal count control CPU]
Next, referring to Fig. 81, a main control reception interrupt process that is performed when the medal count control CPU 501 receives command data from the main control board 441 via the communication circuit SCU0 (see Fig. 43) will be described. Fig. 81 is a flow chart showing the procedure of the main control reception interrupt process.

In the gaming system 400 of this embodiment, data is sent and received in FIFO mode between the main control board 441 and the medal count control board 443, so a receive interrupt occurs on the medal count control board 443 side when 2 bytes of data are received (in units of 2 bytes). However, the present invention is not limited to this, and the medal count control board 443 side may generate a receive interrupt in units of 1 byte to receive commands sent from the main control board 441.

First, the medal count control CPU 501 stores subsequent data (e.g., number of coins inserted, number of coins paid out, various game information, etc.) added to the command received from the main control board 441 in a received data storage area (not shown) provided in the medal count control RAM 503 (S1351).

Next, the medal count control CPU 501 stores the reception status of the command data received from the main control board 441 (status information indicating whether the received command data contains an abnormality such as a parity error or a framing error) in a reception status storage area (not shown) provided in the medal count control RAM 503 (S1352). After processing S1352, the medal count control CPU 501 ends the main control reception interrupt process.

[10-19. Operation of the gaming media lending device (peripheral device)]
Next, with reference to Figures 82 to 85, the contents of various processes executed by the peripheral device control unit 402a of the game media lending device 402 (peripheral device) using a program will be described.

[10-19-1. Power-on processing controlled by the peripheral device control unit]
First, the power-on process (rental device) executed by the peripheral device control unit 402a will be described with reference to Fig. 82. Fig. 82 is a flow chart showing the procedure of the power-on process (rental device).

First, the peripheral device control unit 402a performs an initialization process (S1401). In this process, the peripheral device control unit 402a initializes device settings, etc.

Next, the peripheral device control unit 402a performs a medal count control connection confirmation process (S1402). In this process, the peripheral device control unit 402a performs a process to confirm the connection state with the medal count control board 443. Details of the medal count control connection confirmation process will be described later with reference to FIG. 83.

Next, the peripheral device control unit 402a requests the start of each process (S1403). After the process of S1403, the peripheral device control unit 402a transitions the process to standby. Thereafter, if any event trigger occurs (e.g., a lending operation, etc.), the standby state of the peripheral device control unit 402a is released, and the peripheral device control unit 402a executes the process corresponding to the event trigger that occurred (e.g., see Figures 84 and 85 described below).

[10-19-2. Medal count control connection confirmation process]
Next, the medal count control connection confirmation process performed in S1402 during the power-on process (see FIG. 82) will be described with reference to Fig. 83. Fig. 83 is a flow chart showing the procedure of the medal count control connection confirmation process.

First, the peripheral device control unit 402a determines whether the input port for the PRDY signal (STB signal) or the input port for the EXS signal (data signal) input from the medal count control board 443 to the game media lending device 402 is in the ON state (S1411).

In S1411, when the peripheral device control unit 402a determines that the state of the input port to be monitored (the input port of the PRDY signal or the input port of the EXS signal) is not in the ON state (if S1411 is a NO determination), the peripheral device control unit 402a repeats the determination process of S1411 until the determination process of S1411 becomes a YES determination (until the state of the input port to be monitored becomes the ON state).

On the other hand, in S1411, when the peripheral device control unit 402a determines that the state of the input port to be monitored (the input port of the PRDY signal or the input port of the EXS signal) is in the ON state (if S1411 is determined to be YES), the peripheral device control unit 402a determines whether the ON state of the input port to be monitored (the input port of the PRDY signal or the input port of the EXS signal) is maintained for a predetermined period (200 msec or more) (S1412).

In S1412, when the peripheral device control unit 402a determines that the ON state of the monitored input port (the input port of the PRDY signal or the input port of the EXS signal) has not been maintained for a predetermined period (if S1412 is a NO determination), the peripheral device control unit 402a repeats the determination process of S1412 until the determination process of S1412 becomes a YES determination (until the ON state of the monitored input port is maintained for a predetermined period).

On the other hand, in S1412, when the peripheral device control unit 402a determines that the ON state of the monitored input port (PRDY signal input port or EXS signal input port) has been maintained for a predetermined period (if S1412 is a YES determination), the peripheral device control unit 402a sets the output port of the BRDY signal (STB signal) and the output port of the BRQ signal (data signal) output from the game media lending device 402 to the medal count control board 443 to the ON state (S1413).

Next, the peripheral device control unit 402a performs a response waiting process (S1414). In this process, the peripheral device control unit 402a waits until data such as a command is received (input) from the medal count control board 443. Although not shown, the peripheral device control unit 402a performs a reception process for data sent from the medal count control board 443 (hereinafter referred to as "medal count control reception process") at a fixed cycle of 1 msec. In the process of S1414 as well, this medal count control reception process monitors whether data has been received at a cycle of 1 msec.

Next, the peripheral device control unit 402a determines whether or not a chip individual number command to which one byte of chip individual number data has been added has been received from the medal count control board 443 (S1415).

When the peripheral device control unit 402a determines in S1415 that it has not received the chip individual number command (if S1415 is a NO determination), the peripheral device control unit 402a performs a transmission registration process of a Nack command (non-acknowledge response command) to be transmitted to the medal count control board 443 (S1416). Although not shown, the peripheral device control unit 402a performs a data transmission process (hereinafter referred to as "medal count control transmission process") to the medal count control board 443 at a fixed cycle of 1 msec, and the transmission process of the Nack command registered for transmission in S1416 is executed in this medal count control transmission process. Next, after the process of S1416, the peripheral device control unit 402a returns the process to the process of S1414 (response waiting process) and repeats the processes from S1414 onwards.

On the other hand, in S1415, when the peripheral device control unit 402a determines that a chip individual number command has been received (if S1415 is determined to be YES), the peripheral device control unit 402a determines whether reception of 4 bytes of chip individual number data (all data of the chip individual number) has been completed (S1417).

When the peripheral device control unit 402a determines in S1417 that reception of the 4 bytes of chip individual number data has not been completed (if S1417 returns a NO determination), the peripheral device control unit 402a returns the process to S1414 (response waiting process) and repeats the processes from S1414 onwards.

On the other hand, in S1417, when the peripheral device control unit 402a determines that reception of 4 bytes of chip individual number data is complete (if S1417 is determined to be YES), the peripheral device control unit 402a transmits various data including the received chip individual number data to a management computer (not shown) (S1418). Then, after processing S1418, the peripheral device control unit 402a ends the medal count control connection confirmation process and moves the process to S1403 of the power-on process (see FIG. 82).

As described above, in the gaming system 400 of this embodiment, if an abnormality occurs in the connection between the medal count control board 443 and the gaming media lending device 402 for some reason during startup, and the connection between the two cannot be confirmed or the connection between the two is unstable, the result of the judgment process of S1411 or S1412 will be a NO judgment, and the processing of S1411 or S1412 will be repeated. Therefore, if such a situation occurs, the processing after the medal count control connection confirmation process (processing after S1414 and processing after S1403 in FIG. 82) will not be performed, and gaming media will not be lent out.

[10-19-3. Medal lending process (lending device)]
Next, a medal lending process executed in the game media lending device 402 will be described with reference to Fig. 84. Fig. 84 is a flow chart showing the procedure of the medal lending process.

When the loan button 419 is pressed in the standby state (when the loan switch 419S is turned on), the detection signal generates an event trigger, the standby state of the peripheral device control unit 402a is released, and the medal loan process by the peripheral device control unit 402a is started (S1421).

When the medal lending process is started, the peripheral device control unit 402a first turns off the medal lending available LED (the "Lend" lamp in Figure 37C) provided on the medal lending display unit 427a (S1422).

Next, the peripheral device control unit 402a performs a process for registering the transmission of the medal lending instruction command to be transmitted to the medal count control board 443 (S1423). The transmission of the medal lending instruction command registered for transmission in S1423 is performed in a medal count control transmission process (not shown) executed by the peripheral device control unit 402a at 1 msec intervals.

Next, the peripheral device control unit 402a performs a response waiting process (S1424). In this process, after registering the transmission of the medal lending instruction command, the peripheral device control unit 402a waits until the medal lending instruction command is transmitted to the medal count control board 443 and a response command to the medal lending instruction command is received (input) from the medal count control board 443. Note that the response command reception process during this response waiting process is performed in a medal count control reception process (not shown) that is executed by the peripheral device control unit 402a at 1 msec intervals.

Next, the peripheral device control unit 402a judges whether or not an Ack command has been received from the medal count control board 443 (S1425). When the peripheral device control unit 402a judges in S1425 that an Ack command has not been received (if S1425 returns NO), the peripheral device control unit 402a ends the medal lending process and transitions to standby processing.

On the other hand, when the peripheral device control unit 402a determines in S1425 that an Ack command has been received (if S1425 returns a YES determination), the peripheral device control unit 402a subtracts a predetermined number of points from the number of points (remaining number) of the gaming card (not shown) (S1426). In this embodiment, 10 points (equivalent to 50 gaming media) are subtracted for each lending operation.

Next, the peripheral device control unit 402a displays the subtracted number of points on a three-digit seven-segment LED for displaying the number of points provided on the medal lending display unit 427a (see FIG. 37C) (S1427). Then, after processing S1427, the peripheral device control unit 402a ends the medal lending process and transitions to standby processing.

[10-19-4. Medal counting (accounting) processing (lending device)]
Next, a medal counting (adjustment) process executed in the game media lending device 402 will be described with reference to Fig. 85. Fig. 85 is a flow chart showing the procedure of the medal counting (adjustment) process.

First, the peripheral device control unit 402a performs a response waiting process (S1431). In this process, the peripheral device control unit 402a waits until a command is received (input) from the medal count control board 443. Note that the command reception process during this response waiting process is performed in a medal count control reception process (not shown) that is executed by the peripheral device control unit 402a at 1 msec intervals.

Next, the peripheral device control unit 402a determines whether or not a medal count (lower) instruction command has been received (S1432).

When the peripheral device control unit 402a determines in S1432 that it has not received a medal counting (lower) instruction command (if S1432 returns a NO determination), the peripheral device control unit 402a ends the medal counting (settlement) process and transitions to standby processing.

On the other hand, when the peripheral device control unit 402a determines in S1432 that it has received a medal count (lower) instruction command (if S1432 is a YES judgment), the peripheral device control unit 402a determines whether or not counting (settlement) is possible (S1433). Note that in the judgment process of S1433, if the current situation is that no gaming card is inserted, gaming media is being lent, or an abnormality has occurred in the gaming media lending device 402 (peripheral device), counting (settlement) is not possible (NO judgment), and if the situation is anything other than these, counting (settlement) is possible (YES judgment).

When the peripheral device control unit 402a determines in S1433 that counting (adjustment) is not possible (if S1433 is a NO determination), the peripheral device control unit 402a performs a transmission registration process of a Nack command to be transmitted to the medal count control board 443 (S1434). The transmission of the Nack command registered for transmission in S1434 is performed in a medal count control transmission process (not shown) executed by the peripheral device control unit 402a at 1 msec intervals. Then, after processing S1434, the peripheral device control unit 402a ends the medal count (adjustment) process and transitions to standby processing.

On the other hand, in S1433, when the peripheral device control unit 402a determines that counting (settlement) is acceptable (if S1433 is determined to be YES), the peripheral device control unit 402a performs a transmission registration process of an Ack command to be transmitted to the medal count control board 443 (S1435). The transmission of the Ack command registered for transmission in S1435 is performed in a medal count control transmission process (not shown) executed by the peripheral device control unit 402a at 1 msec intervals.

Next, the peripheral device control unit 402a turns off the gaming medium lending available LED (the "Lend" lamp in FIG. 37C) provided on the medal lending display unit 427a (S1436). Next, the peripheral device control unit 402a performs a response waiting process (S1437). In this process, the peripheral device control unit 402a waits until a command is received (input) from the medal count control board 443. Note that the command receiving process during this response waiting process is performed in the medal count control receiving process (not shown) which is executed by the peripheral device control unit 402a at 1 msec intervals.

Next, the peripheral device control unit 402a determines whether or not a medal count (upper) instruction command has been received (S1438).

When the peripheral device control unit 402a determines in S1438 that it has received a medal count (higher order) instruction command (if S1438 is a YES determination), the peripheral device control unit 402a performs a transmission registration process for an Ack command to be transmitted to the medal count control board 443 (S1439). Note that the transmission of the Ack command registered in S1439 is performed in a medal count control transmission process (not shown) executed by the peripheral device control unit 402a at 1 msec intervals.

Then, the peripheral device control unit 402a performs a medal count information reflection process (S1440). In this process, the peripheral device control unit 402a obtains the settlement number of game media based on the received medal count (lower) instruction command and medal count (upper) instruction command, adds the frequency corresponding to the settlement number to the current frequency, and displays the frequency after the addition on a three-digit seven-segment frequency display LED (see FIG. 37C) provided on the medal lending display unit 427a, and writes it to the game card.

Next, the peripheral device control unit 402a turns on the gaming medium lending available LED (the "Lend" lamp in FIG. 37C) (S1441). Then, after processing S1441, the peripheral device control unit 402a ends the medal counting (settlement) process and transitions to standby processing.

Returning to the processing of S1438 again, when the peripheral device control unit 402a determines in S1438 that it has not received a medal count (higher order) instruction command (if S1438 returns a NO determination), the peripheral device control unit 402a performs a transmission registration process for a Nack command to be transmitted to the medal count control board 443 (S1442). The transmission of the Nack command registered for transmission in S1442 is performed in a medal count control transmission process (not shown) executed by the peripheral device control unit 402a at 1 msec intervals. After processing of S1442, the peripheral device control unit 402a ends the medal count (settlement) process and transitions to standby processing.

[10-20. Operation of the Sub-Control Board]
Next, with reference to Figures 86 and 87, the contents of various processes executed by the sub-CPU (not shown) of the sub-control board 442 using programs will be described.

[10-20-1. Processing when receiving main control command]
First, a main control command reception process executed in the sub-control board 442 will be described with reference to Fig. 86. Fig. 86 is a flow chart showing the procedure of the main control command reception process.

First, the sub-CPU performs a process of acquiring received data (S1501). In this process, the sub-CPU performs a process of acquiring transmission data (commands) received from the main control board 441 in a reception interrupt process (not shown). In the pachislot 401, data is transmitted from the main control board 441 to the sub-control board 442 in packets of 8 bytes.

Then, the sub CPU determines whether one packet (8 bytes) of received data is present (S1502). If the sub CPU determines in S1502 that there is no received data (if S1502 returns NO), the sub CPU ends the main control command reception process.

On the other hand, when the sub CPU determines in S1502 that there is received data (if S1502 returns YES), the sub CPU performs analysis processing of the received data (S1503). In this analysis processing, the sub CPU performs a sum check processing on the received data, a determination processing of the command ID (command type) included in the received data, a determination processing of the number of data units of the parameter added to the command ID, etc.

Then, the sub-CPU judges whether the received data is normal or not (S1504). In this judgment process, the sub-CPU judges that the received data is normal if the result of the analysis process of the received data in S1503, for example, the sum value of the received data, the command ID (command type), the number of data units of the parameter added to the command ID, etc., are normal. Note that if the number of data units of the parameter is normal, the number corresponds to the command ID (command type).

When the sub-CPU determines in S1504 that the received data is not normal (if S1504 returns NO), the sub-CPU terminates the main control command reception process.

On the other hand, when the sub-CPU determines in S1504 that the received data is normal (S1504 is a YES determination), the sub-CPU determines whether the received data (command) is a game progress command (S1505). This determination process is performed by referring to the command ID (information indicating the command type) included in the received data.

The command ID is assigned a specific value according to each event that triggers the transmission of a command from the main control board 441 to the sub-control board 442, and the "game progress command" referred to here is a command transmitted from the main control board 441 to the sub-control board 442 when various essential events related to the progress of the game occur, such as a bet operation, a start operation, a stop operation, etc. On the other hand, commands transmitted from the main control board 441 to the sub-control board 442 when various events not related to the progress of the game occur, such as a return operation, a setting change/confirmation operation, pressing the medal count clear switch 443a (clearing the stored number), no operation, etc., are referred to below as "non-game progress commands". In addition, the number of medals (reserved number) displayed on the 5-digit 7-segment LED for credit display in the medal count display unit 426b is information managed by the medal count control board 443, so commands related to the operation of returning the number of medals (reserved number) (writing operation to the card in the game media lending device 402 (Sand)) are not sent to the sub-control board 442.

When the sub-CPU determines in S1505 that the received data (command) is a game progress command (YES in S1505), the sub-CPU performs game progress command processing (S1506). In this processing, the sub-CPU performs, for example, processing to determine the presentation content according to the type of the received command. Then, after processing S1506, the sub-CPU ends the main control command reception processing.

On the other hand, when the sub-CPU determines in S1505 that the received data (command) is not a game progress command (if S1505 returns NO), the sub-CPU performs non-game progress command processing (S1507). In this processing, the sub-CPU performs, for example, setting processing related to the notification of information corresponding to the type of the received command. Details of the non-game progress command processing will be described later with reference to FIG. 87. After processing S1507, the sub-CPU ends the main control command reception processing.

[10-20-2. Non-game progress command processing]
Next, the non-game progress command processing performed in S1507 during the main control command reception process (see Fig. 86) will be described with reference to Fig. 87. Fig. 87 is a flow chart showing the procedure for the non-game progress command processing.

First, the sub-CPU (not shown) determines whether the received data (command) is a setting change command (start) (S1511).

When the sub-CPU judges in S1511 that the received data is a setting change command (start) (if S1511 is judged as YES), the sub-CPU performs a maintenance menu start request process (S1512). In the slot machine 401, when the setting change process is started by an attendant of the game parlor, etc., and the setting change command (start) is transmitted from the main control board 441 to the sub-control board 442, a menu screen (maintenance menu) listing multiple maintenance items is displayed on the display screen of the display device 413, etc., on the sub-control board 442 side. The maintenance menu is also called a hall menu. Therefore, in the process of S1512, the sub-CPU performs various processes required to start displaying the maintenance menu, and thus the display of the maintenance menu starts on the display screen of the display device 413. Then, after the process of S1512, the sub-CPU ends the non-game progress command process, and also ends the main control command reception process (FIG. 86), which is the process called from the process.

On the other hand, when the sub CPU determines in S1511 that the received data is not a setting change command (start) (if S1511 is a NO determination), the sub CPU determines whether the received data (command) is a setting change command (end) (S1513). When the sub CPU determines in S1513 that the received data is not a setting change command (end) (if S1513 is a NO determination), the sub CPU performs the process of S1517 described below.

On the other hand, when the sub CPU determines in S1513 that the received data is a setting change command (end) (if S1513 returns a YES determination), the sub CPU performs a maintenance menu end request process (S1514). In the process of S1514, the sub CPU performs various processes required to end the display of the maintenance menu.

Then, the sub-CPU judges whether or not the medal count clear sound is in a standby state for output (S1515). When the sub-CPU judges in S1515 that the medal count clear sound is not in a standby state for output (if S1515 is judged as NO), the sub-CPU ends the non-game progress command processing and also ends the main control command reception processing (FIG. 86), which is the processing called from this processing. In this case, the display of the maintenance menu is also terminated.

On the other hand, when the sub-CPU judges in S1515 that the medal count clear sound is in the output standby state (if S1515 is judged as YES), the sub-CPU performs the medal count clear sound output (shot) request registration process (S1516). This process starts the medal count clear sound shot playback (for example, a 30-second sound), and notifies the user that the medal count clear switch 443a has been pressed. That is, if the medal count clear sound is in the output standby state when the setting change process is completed, the medal count clear sound shot playback is started. In this case, the medal count clear sound is output after the setting change operation or the setting confirmation operation is completed, so that the staff of the game arcade can check (visually) that the accumulated number of game values displayed on the 7-segment LED has been cleared. After the process of S1516, the sub-CPU ends the non-game progress command process, and also ends the main control command reception process (FIG. 86), which is the process called by the process.

Here, the process returns to S1513 again. If S1513 returns NO, the sub-CPU determines whether the received data (command) is a medal count clear start command (S1517). If the sub-CPU determines in S1517 that the received data is not a medal count clear start command (if S1517 returns NO), the sub-CPU performs the process of S1521, which will be described later.

On the other hand, when the sub-CPU determines in S1517 that the received data is a medal count clear start command (if S1517 returns a YES determination), the sub-CPU determines whether or not the maintenance menu is being displayed (S1518).

When the sub-CPU determines in S1518 that the maintenance menu is not being displayed (if S1518 is a NO determination), the sub-CPU performs a medal count clear sound output (shot) request registration process (S1519). This process starts a shot playback of the medal count clear sound (e.g., a 30-second ringing), and notifies the player that the medal count clear switch 443a has been pressed. As a result, the staff member who pressed the medal count clear switch 443a can know that the pressing operation was performed correctly without checking the credit display (5-digit 7-segment LED) of the medal count display unit 426b. Then, after the process of S1519, the sub-CPU ends the non-game progress command process, and also ends the main control command reception process (FIG. 86), which is the process called by this process.

In addition, as a notification form of the pressing operation (medal count clear) on the medal count clear switch 443a, instead of the output (shot playback) of the medal count clear sound by the speaker, the LED group 435 may emit light (shot playback) of the medal count clear pattern. In addition, the shot playback of the LED means that the operation of making the LED emit light in a predetermined pattern for a preset playback (output) period is executed only once. In this case, in each of the above-mentioned S1516 and S1519, instead of the medal count clear sound output (shot) request registration process, the medal count clear pattern emission (shot) request registration process may be executed, and the medal count clear pattern shot playback may be performed. In addition, for example, as a notification form of the pressing operation (medal count clear) on the medal count clear switch 443a, both the medal count clear sound output (shot playback) by the speaker and the medal count clear pattern emission (shot playback) by the LED group 435 may be used. In this case, in each of S1516 and S1519, both a medal count clear sound output (shot) request registration process and a medal count clear pattern light emission (shot) request registration process may be performed, so that both the medal count clear sound shot playback and the medal count clear pattern shot playback are performed.

On the other hand, when the sub-CPU determines in S1518 that the maintenance menu is being displayed (S1518 is a YES determination), the sub-CPU sets a standby state for the output of the medal count clear sound (S1520). In other words, if the maintenance menu is being displayed when the medal count clear switch 443a is pressed, the medal count clear sound shot playback is not started and the standby state is entered. Then, after processing S1520, the sub-CPU ends the non-game progress command processing, and also ends the main control command reception processing (FIG. 86), which is the processing called from that processing.

Now, the process returns to S1517 again. If S1517 returns NO, the sub-CPU determines whether the received data (command) is a medal count clear end command (S1521).

When the sub-CPU determines in S1521 that the received data is not a medal count clear end command (if S1521 is a NO judgement), the sub-CPU performs the process of S1525 described below. On the other hand, when the sub-CPU determines in S1521 that the received data is a medal count clear end command (if S1521 is a YES judgement), the sub-CPU determines whether or not the maintenance menu is being displayed (S1522).

When the sub-CPU determines in S1522 that the maintenance menu is being displayed (if S1522 is a YES judgment), the sub-CPU ends the non-game progress command processing and also ends the main control command reception processing (FIG. 86) which is the processing called by this processing. On the other hand, when the sub-CPU determines in S1522 that the maintenance menu is not being displayed (if S1522 is a NO judgment), the sub-CPU determines whether or not the medal count clear sound is being output (S1523).

When the sub-CPU determines in S1523 that the medal count clear sound is not being output (if S1523 returns a NO judgment), the sub-CPU ends the non-game progress command processing and also ends the main control command reception processing (Figure 86), which is the processing called by this processing.

On the other hand, when the sub CPU determines in S1523 that the medal count clear sound is being output (if S1523 is a YES determination), the sub CPU performs a medal count clear sound stop registration process (S1524). This process stops the shot playback of the medal count clear sound. In other words, if the medal count clear sound is being output when the medal count clear process ends, the shot playback of the medal count clear sound is stopped midway when the medal count clear process ends. Then, after the process of S1524, the sub CPU ends the non-game progress command process, and also ends the main control command reception process (FIG. 86), which is the process called by this process.

Now, returning to the processing of S1521 again, if S1521 is judged as NO, the sub-CPU performs processing when another non-game progress related command is received (S1525). In this processing, the sub-CPU performs processing when receiving a non-game progress related command other than the setting change command (start), setting change command (end), medal count clear start command, and medal count clear end command, which corresponds to the type of non-game progress related command received. Then, after processing of S1525, the sub-CPU ends the non-game progress related command processing, and also ends the main control command reception processing (Fig. 86), which is the processing called from this processing.

[10-21. Various Modifications]
The configuration and operation of the gaming system, gaming machine, and gaming media rental device according to one embodiment of the present invention have been described above, including their effects. However, the present invention is not limited to the above embodiment, and includes various other embodiments and modifications without departing from the gist of the present invention described in the claims.

[10-21-1. Various modified examples of game start conditions]
In the gaming system 400, as explained in the game start process in Fig. 62 above, unless the VL signal (connection signal) input from the gaming medium lending device 402 to the slot machine 401 is in an ON state, the game will not start. However, the present invention is not limited to this, and the following various modified examples may be adopted as the game start conditions of the slot machine 401 (second gaming machine). Even if the game start conditions of the following various modified examples are adopted, it is possible to introduce and operate the medal-less gaming machine with only a simple modification of the program, just like the slot machine 401.

<Modification 1>
As the game start condition of the pachislot 401, for example, a condition considering the on/off state of the start switch 422S and the on/off state of the VL signal (connection signal) input to the main control board 441 may be used. In Modification 1, an example of such a condition is described. In this example, a configuration example is described in which the determination process of the condition related to the game start and the signal corresponding to the determination result are realized by hardware.

Figure 88 shows a schematic diagram of a gaming system 601 in variant 1. Note that in the gaming system 601 of this example shown in Figure 88, components similar to those in the gaming system 400 shown in Figures 39, 41, and 42 are denoted with the same reference numerals. Also, the configuration diagram of the gaming system 601 of this example shown in Figure 88 shows only the components necessary to explain the features of variant 1, and components not shown are similar to those in the gaming system 400.

As is clear from a comparison of the gaming system 601 of this example shown in Figure 88 with the gaming system 400 shown in Figures 39, 41, and 42, the configuration of the gaming system 601 in this example is the same as that of the gaming system 400, except that an AND circuit 602 is added to the door relay board 444.

In this example, one input terminal of the AND circuit 602 is connected to the start switch 422S, and the other input terminal is connected to the VL signal input port of the medal count control board 443 (a signal line for transmitting the VL signal provided between the game ball connection terminal board 445 and the medal count control board 443). In addition, the output terminal of the AND circuit 602 is connected to the main control microprocessor 450 via the multifunction LSI 444a (slave) in the door relay board 444 and the multifunction LSI 453 (master) in the main control board 441.

In this example, the detection signal of the start switch 422S and the VL signal from the game medium lending device 402 are input to the AND circuit 602, and the logical product of both input signals is output from the output terminal of the AND circuit 602. Specifically, when the detection signal of the start switch 422S is in the ON state and the VL signal is in the ON state (when the conditions for starting a game are met), a High level signal is output from the AND circuit 602, and otherwise (when the conditions for starting a game are not met), a Low level signal is output from the AND circuit 602.

The output signal from the AND circuit 602 is then input to the main control microprocessor 450 via the multifunction LSI 444a (slave) in the door relay board 444 and the multifunction LSI 453 (master) in the main control board 441. Therefore, in this example, whether or not to start playing is automatically determined depending on the level (High or Low) of the output signal from the AND circuit 602 input to the main control microprocessor 450.

In this example, the VL signal input to the AND circuit 602 is directly obtained from the VL signal input port of the medal count control board 443 (signal line for VL signal transmission provided between the game ball connection terminal board 445 and the medal count control board 443), but the present invention is not limited to this. For example, the VL signal after being input to the medal count control board 443 may be input to the AND circuit 602. In this case, as shown by the dashed line in FIG. 88, the VL signal output from the medal count control board 443 via the buffer IC 463 in the medal count control board 443, the medal count control microprocessor 460, and another buffer IC 603 is input to the AND circuit 602. In this configuration, the signal line connecting the VL signal input port of the medal count control board 443 (signal line for VL signal transmission provided between the game ball connection terminal board 445 and the medal count control board 443) and the other input terminal of the AND circuit 602 is omitted.

As in this example, if the process of determining the conditions for starting play on the pachislot 401 and the signal corresponding to the result of that determination are realized in hardware, it is possible to obtain effects such as reducing the processing load on the main control microprocessor 450 (main CPU 501) and reducing the program capacity.

<Modification 2>
As the game start condition of the slot machine 401, for example, a condition considering the on/off state of the detection signal (multiplication number signal) of the MAXBET switch 416S or the 1BET switch 417S and the on/off state of the VL signal (connection signal) input to the slot machine 1 may be used. In the modified example 2, an example of such a case will be described. In this example, a configuration example will be described in which the judgment process of the condition related to the game start and the signal corresponding to the judgment result are realized by hardware.

Figure 89 shows a schematic diagram of a gaming system 611 in Modification 2. Note that in this example of gaming system 611 shown in Figure 89, components similar to those in the gaming system 400 shown in Figures 39, 41, and 42 are denoted with the same reference numerals. Also, the configuration diagram of this example of gaming system 611 shown in Figure 89 shows only the components necessary to explain the features of Modification 2, and components not shown are similar to those in the gaming system 400.

As is clear from a comparison of the gaming system 611 of this example shown in Figure 89 with the gaming system 400 shown in Figures 39, 41, and 42, the configuration of the gaming system 611 in this example is the same as that of the gaming system 400, except that a first AND circuit 612 and a second AND circuit 613 are added to the door relay board 444.

In this example, one input terminal of the first AND circuit 612 is connected to the MAXBET switch 416S, and the other input terminal is connected to the VL signal input port of the medal count control board 443 (a signal line for transmitting the VL signal provided between the game ball connection terminal board 445 and the medal count control board 443). In addition, the output terminal of the first AND circuit 612 is connected to the main control microprocessor 450 via the multifunction LSI 444a (slave) in the door relay board 444 and the multifunction LSI 453 (master) in the main control board 441.

That is, in the first AND circuit 612, the detection signal of the MAXBET switch 416S and the VL signal from the gaming medium lending device 402 are input to the first AND circuit 612, and the logical product of both input signals is output from the output terminal of the first AND circuit 612. Specifically, when the detection signal of the MAXBET switch 416S is in the ON state and the VL signal is in the ON state, the first AND circuit 612 outputs a High level signal, and otherwise the first AND circuit 612 outputs a Low level signal.

Meanwhile, in this example, one input terminal of the second AND circuit 613 is connected to the 1BET switch 417S, and the other input terminal is connected to the VL signal input port of the medal count control board 443 (a signal line for transmitting the VL signal provided between the game ball connection terminal board 445 and the medal count control board 443). In addition, the output terminal of the second AND circuit 613 is connected to the main control microprocessor 450 via the multifunction LSI 444a (slave) in the door relay board 444 and the multifunction LSI 453 (master) in the main control board 441.

That is, in the second AND circuit 613, the detection signal of the 1BET switch 417S and the VL signal from the gaming medium lending device 402 are input to the second AND circuit 613, and the logical product of both input signals is output from the output terminal of the second AND circuit 613. Specifically, when the detection signal of the 1BET switch 417S is in the ON state and the VL signal is in the ON state, a High level signal is output from the second AND circuit 613, and otherwise a Low level signal is output from the second AND circuit 613.

In this example, a state in which a high-level output signal is output from the first AND circuit 612 or the second AND circuit 613 indicates that the conditions for starting a game are met, and any other state indicates that the conditions for starting a game are not met.

The output signals from the first AND circuit 612 and the second AND circuit 613 are input to the main control microprocessor 450 via the multifunction LSI 444a (slave) in the door relay board 444 and the multifunction LSI 453 (master) in the main control board 441. Therefore, in this example, whether or not to start playing is automatically determined according to the state of the output signals from the first AND circuit 612 and the second AND circuit 613 input to the main control microprocessor 450 (the combination state of the level of the output signal from the first AND circuit 612 and the level of the output signal from the second AND circuit 613).

In this example, the VL signal input to the first AND circuit 612 and the second AND circuit 613 is directly obtained from the VL signal input port of the medal count control board 443 (a signal line for transmitting the VL signal provided between the game ball connection terminal board 445 and the medal count control board 443), but the present invention is not limited to this. For example, the VL signal after being input to the medal count control board 443 may be input to the first AND circuit 612 and the second AND circuit 613. In this case, as shown by the dashed lines in FIG. 89, the VL signal output from the medal count control board 443 via the buffer IC 463, the medal count control microprocessor 460, and the other buffer IC 614 in the medal count control board 443 is input to the first AND circuit 612 and the second AND circuit 613. In addition, in this configuration, the signal lines connecting the VL signal input port of the medal count control board 443 (the signal line for transmitting the VL signal provided between the game ball connection terminal board 445 and the medal count control board 443) and the other input terminals of the first AND circuit 612 and the second AND circuit 613 are omitted.

As in this example, if the process of determining the conditions for starting play on the pachislot 401 and the signal corresponding to the result of that determination are realized in hardware, it is possible to obtain effects such as reducing the processing load on the main control microprocessor 450 (main CPU 501) and reducing the program capacity.

<Modification 3: Modification of the Output Function of External Terminal Signal>
In the gaming system 400, a connection mechanism 445a for connecting the pachislot 401 and the gaming medium lending device 402 is provided in the gaming ball etc. connection terminal board 445.

Here, we explain a modified method (Modification 3) for outputting an external terminal signal from the main control board 441 to the peripheral device 500. Even if the external terminal signal output method of Modification 3 below is adopted, it is possible to introduce and operate the medal-less gaming machine with only a simple modification of the program, just like the above embodiment.

Figure 90 is a schematic diagram of the gaming system 400 and the gaming system of variant 3. Note that Figure 90A is a schematic diagram of the gaming system 400, and Figure 90B is a schematic diagram of the gaming system 621 of variant 3. In each gaming system shown in Figures 90A and 90B, components similar to those of the gaming system 400 shown in Figures 39, 41, and 42 are indicated with the same reference numerals. Also, the schematic diagrams of each gaming system shown in Figures 90A and 90B show only the components necessary to explain the method of outputting external terminal signals, and components not shown are similar to those in the above embodiment.

(1) Method of outputting external terminal signals in the gaming system 400 To facilitate understanding of the difference in the method of outputting external terminal signals between the gaming system 400 and variant example 3, the method of outputting external terminal signals in the gaming system 400 will first be described with reference to FIG. 90A.

When an external terminal signal is output from the main control board 441 to the peripheral device 500, the main control microprocessor 450 in the main control board 441 first generates a command to which information about the external terminal signal is added, and then transmits the command by serial communication to the medal count control microprocessor 460 in the medal count control board 443. Next, the medal count control microprocessor 460, which has received the command, outputs an external terminal signal to the buffer IC 463 in the medal count control board 443. The external terminal signal output to the buffer IC 463 is then output to the peripheral device 500 via the connection mechanism 445a in the game ball etc. connection terminal board 445.

For example, when outputting a gaming medium insertion signal to the peripheral device 500 as an external terminal signal, the main control microprocessor 450 first generates an external terminal gaming medium insertion command with the number of gaming media inserted (e.g., "3") added at the timing of operation of the start lever 422, and transmits the external terminal gaming medium insertion command to the medal count control board 443 (medal count control microprocessor 460) via serial communication. Next, the medal count control microprocessor 460 generates a gaming medium insertion signal pulse at the timing of receiving the external terminal gaming medium insertion command, and outputs the gaming medium insertion signal pulse to the connection mechanism part 445a in the gaming ball etc. connection terminal board 445 via the buffer IC 463.

For example, when a security signal is output to the peripheral device 500 as an external terminal signal, the main control microprocessor 450 first generates an external terminal security command with a security activation state added when it detects the door open state or when it detects the release of the door open state, and transmits the external terminal security command to the medal count control board 443 (medal count control microprocessor 460) via serial communication. Next, when it receives the external terminal security command, the medal count control microprocessor 460 outputs a signal (security signal) according to the security state to the connection mechanism unit 445a.

The pachislot 401 is a medal-less gaming machine, and is therefore not equipped with, for example, a medal selector or a hopper device. Therefore, errors detected by the main control board 441 of the pachislot 401 are RAM errors and errors detected by the medal count control board 443.

(2) External Terminal Signal Output Method in Modification 3 Next, an external terminal signal output method in the gaming system 621 in modification 3 will be described with reference to FIG. 90B.

When an external terminal signal is output from the main control board 441 to the peripheral device 500, the main control microprocessor 450 in the main control board 441 first outputs an external terminal signal to the multifunction LSI 453 (master) in the main control board 441. Next, the external terminal signal output to the multifunction LSI 453 (master) is output to another buffer IC 603 provided in the medal count control board 443 via a signal line connecting the multifunction LSI 453 (master) and the other buffer IC 603.

Then, the medal count control microprocessor 460 in the medal count control board 443 acquires an external terminal signal from another buffer IC 603, and outputs the external terminal signal to the buffer IC 463 in the medal count control board 443. The external terminal signal output to the buffer IC 463 is then output to the peripheral device 500 via the connection mechanism 445a in the game ball etc. connection terminal board 445.

<Modification 4>
In the gaming systems of the above embodiment and the various modified examples, a configuration example in which the functional part (connection mechanism part 445a) of the external centralized terminal board is provided in the gaming ball etc. connection terminal board 445 has been described, but the present invention is not limited to this. For example, in the gaming systems of the above embodiment and the various modified examples, an external centralized terminal board may be provided instead of the gaming ball etc. connection terminal board 445, and the functional part of the gaming ball etc. connection terminal board 445 may be provided in the external centralized terminal board. In this case, the functional part of the gaming ball etc. connection terminal board 445 in the external centralized terminal board is connected to the gaming medium lending device 402.

In such a configuration, the output method of the signal (hereinafter referred to as the "connection terminal signal") output from the functional section of the game ball etc. connection terminal board 445 in the external centralized terminal board to the game medium lending device 402 can be the same as the output method of the external terminal signal described in the above embodiment and modified example 3. Specifically, in the description of the output method of the external terminal signal in the above embodiment and modified example 3 (Figures 90A and 90B), the external terminal signal can be replaced with the connection terminal signal.

Even if the configuration of variant 4 and the method of outputting the connection terminal signal are adopted, it is possible to introduce and operate a medal-less gaming machine with only a simple modification of the program, just like in the above embodiment.

<Modification 5>
In the gaming system 400, a two-wire synchronous bidirectional protocol is used as the data input/output specification (pseudo communication specification) between the slot machine 401 (the medal count control board 443) and the gaming medium lending device 402. In the gaming system 400, the data input/output (data communication) between the slot machine 401 (the medal count control board 443) and the gaming medium lending device 402 performed in the settlement process of the gaming medium is also performed using the two-wire synchronous bidirectional protocol.

In variant example 5, a configuration is described in which the on/off state of the STB signal and data signal exchanged between devices during data input/output (data communication) performed when the settlement button 418 is pressed is controlled in a devised way to provide a function for transitioning the operating mode to the settlement mode.

Figure 91 shows an example of level control of the PRDY signal (STB signal) and XES signal (data signal) output (transmitted) from the medal count control board 443 of the slot machine 401 to the game media lending device 402, which is performed in the period from when the settlement button 418 is pressed (settlement start) to the end of the settlement mode (settlement end) in this example of the gaming system 400, and an example of level control of the BRDY signal (STB signal) and BRQ signal (data signal) output (transmitted) from the game media lending device 402 to the medal count control board 443. Note that the level control of the PRDY signal and XES signal described below is performed by the medal count control microprocessor 460 (medal count control CPU 501) of the medal count control board 443, and the level control of the BRDY signal and BRQ signal is performed by the peripheral device control unit 402a of the game media lending device 402.

First, at time t0, when the settlement button 418 is pressed, the settlement switch 418S changes from the OFF state to the ON state.

This change in the state of the settlement switch 418S triggers a request from the medal count control board 443 to the game media lending device 402 to switch to settlement mode. Specifically, this request is made by changing the level of the PRDY signal output from the medal count control board 443 to the game media lending device 402 from Low (standby state, OFF state) to High (ON state), and by changing the level of the EXS signal from High to Low. At this time, the levels of the BRDY signal and BRQ signal output from the game media lending device 402 to the medal count control board 443 are both maintained at the High level.

That is, in this example, when the settlement button 418 is pressed at time t0, a state occurs in which the levels of the PRDY signal and the BRDY signal both become High. However, because data is input and output between the medal count control board 443 and the game medium lending device 402 in a polling format, such a combination of the level state of the PRDY signal (STB signal) and the level state of the BRDY signal (STB signal) does not occur in normal data input and output operations. Therefore, the game medium lending device 402 detects the level state between the PRDY signal and the BRDY signal (a state in which the levels of the PRDY signal and the BRDY signal both become High), which does not occur in such normal data input and output operations, and determines that a transition to settlement mode has been requested from the medal count control board 443.

Next, when the game media lending device 402 detects that a request to switch to settlement mode has been made, an Ack response (acknowledgement response) is sent from the game media lending device 402 to the medal count control board 443 at time t1. Specifically, this Ack response is sent by changing the BRDY signal output from the game media lending device 402 to the medal count control board 443 from a high level to a low level at time t1, and maintaining the level of the BRQ signal at a high level.

Next, when the medal count control board 443 confirms an Ack response from the game media lending device 402 (when it confirms the transition to the settlement mode), it returns the PRDY signal level to a low level (standby state) and the EXS signal level to a high level at time t2, and then the control state of the medal count control board 443 transitions to a standby state. Next, after the transition to the settlement mode is confirmed in the game media lending device 402, at time t3, it returns the BRDY signal level to a low level and the BRQ signal level to a high level, and then the control state of the game media lending device 402 transitions to a standby state. The transition process to the settlement mode is completed by the series of level controls of the PRDY signal, EXS signal, BRDY signal, and BRQ signal described above.

Then, the game media settlement operation is performed by repeating the operation of outputting the digit number information of the settlement number of the game media and the settlement number information corresponding to the digit number from the medal number control board 443 to the game media lending device 402 in this order. For example, when the settlement number of the game media is "1308", the digit number information "4 (fourth digit)", the fourth digit settlement number information "1", the digit number information "3 (third digit)", the third digit settlement number information "3", the digit number information "1 (first digit)" and the first digit settlement number information "8" are output in this order from the medal number control board 443 to the game media lending device 402. Note that in this example, since the second digit settlement number information is "0", the second digit number information and the settlement number information are not output. Also, in this example, the digit number information "0" is used as data for determining the end of the settlement mode, as described later.

As shown in FIG. 91, when the transmission (setting) of the settlement number information of the gaming medium starts (time t4), the level of the PRDY signal is changed from Low to High, and during the transmission period of the settlement number information (time t4 to t5), the level of the PRDY signal is maintained at a High level (on state). During the transmission period of this digit number information (time t4 to t5), the level of the EXS signal is controlled according to the digit number information. Then, when the transmission of the digit number information ends (time t5), the level of the PRDY signal is changed from High to Low. Thereafter, when the transmission (setting) of the settlement number information starts (time t6), the level of the PRDY signal is maintained at a Low level, and during the transmission period of the settlement number information (time t6 to t7), the level of the PRDY signal is maintained (Low). During the transmission period of this settlement number information (time t6 to t7), the level of the EXS signal is controlled according to the settlement number information.

Then, after the transmission of all the digit information and settlement number information of the settlement number of the gaming medium has been completed, at time t8, the level of the PRDY signal is changed from Low to High to start the end process of the settlement mode. That is, in this example, the end process of the settlement mode is started by the same level control as the level control at the start of the transmission (setting) of the digit information (time t4).

After that, for a predetermined period of time (until time t9), the PRDY signal level (High) is maintained unchanged, and the EXS signal level (High) is also maintained unchanged. In other words, after the start of the settlement mode termination process, during the period from time t8 to t9 when the PRDY signal is maintained at a High level, a state in which the EXS signal is maintained at a High level (unchanged state) is generated.

Therefore, during the period from time t8 to t9 when the PRDY signal is maintained at a high level after the end processing of the settlement mode has started, a situation similar to that occurs when "0" is transmitted from the medal count control board 443 to the game media lending device 402 as the number of digits information for the settlement number of game media. In other words, during the period from time t8 to t9 when the PRDY signal is maintained at a high level after the end processing of the settlement mode has started, the medal count control board 443 is actually transmitting 0 digits as the number of digits information (impossible information) to the game media lending device 402. The game media lending device 402 then detects the transmission of this erroneous information, and based on this detection, determines that the settlement mode has ended, and returns the level of the BRDY signal from low to high (standby state) (time t10), completing the series of settlement operations.

The output operation of the number of digits information and settlement number information for the gaming medium settlement number performed during the period from time t4 to t7 (level control of the PRDY signal, EXS signal, BRDY signal, and BRQ signal during the gaming medium settlement operation) is performed by normal data input/output operation in the two-wire synchronous method.

In addition, in this example, a function has been provided to transition the operating mode to the settlement mode by utilizing data input/output specifications (two-wire synchronous bidirectional protocol) when the settlement button 418 is pressed, but the present invention is not limited to this. For example, a function may be provided to transition the operating mode to the card return mode by performing control similar to the level control of the PRDY signal, EXS signal, BRDY signal, and BRQ signal described above when the card return button 421 is pressed. Also, for example, a function may be provided to transition the operating mode to the lending mode by performing control similar to the level control of the PRDY signal, EXS signal, BRDY signal, and BRQ signal described above when the lending button 419 is pressed.

In addition, in a gaming system that employs the various functions described above in variant 5, similar to gaming system 400, it is possible to introduce and operate a medal-less gaming machine with just a simple modification of the program.

<Modification 6>
In variant example 6, a configuration example is described in which a disconnection detection circuit is provided on the signal line (a signal line used in a two-wire synchronous bidirectional protocol) connecting the medal count control board 443 and the gaming medium lending device 402 in the gaming system 400 and the various variant examples described above.

Figure 92 shows a schematic configuration of the connection wiring section 645 between the medal count control board 443 and the gaming medium lending device 402 in the gaming system of this example. Note that in the gaming system of this example shown in Figure 92, the same components as those in the gaming system 400 shown in Figures 39, 41, and 42 are denoted by the same reference numerals.

As shown in FIG. 92, the connection wiring unit 645 has a PRDY signal line and an EXS signal line for outputting a PRDY signal and an EXR signal, respectively, from the medal count control board 443 to the game medium lending device 402, a BRDY signal line and a BRQ signal line for outputting a BRDY signal and a BRQ signal, respectively, from the game medium lending device 402 to the medal count control board 443, and a break detection circuit 650 provided for the BRQ signal line. Although not shown in FIG. 92, the connection wiring unit 645 also has a signal line for transmitting a VL signal (connection signal) between the game medium lending device 402 and the medal count control board 443 (see FIG. 88, etc.).

The disconnection detection circuit 650 is composed of a transistor 651 and a resistor 652 (commonly known as a pull-up resistor). The base terminal of the transistor 651 is connected to the BRQ signal line, the collector terminal is connected to one terminal of the resistor 652 and the medal count control board 443, and the emitter terminal is grounded (GND). The other terminal of the resistor 652 is connected to the +5V power supply voltage terminal.

When a disconnection detection circuit 650 having such a configuration is provided for the BRQ signal line, when the BRQ signal line is not disconnected, a small current flows from the BRQ signal line to the base terminal of the transistor 651, the transistor 651 is turned on, and a current flows between the collector terminal and the emitter terminal of the transistor 651. In this case, the voltage of the collector terminal of the transistor 651 becomes a low level, and the low level voltage signal is output to the medal count control board 443 as the output signal of the disconnection detection circuit 650.

On the other hand, when a break occurs in the BRQ signal line, no current flows from the BRQ signal line to the base terminal of the transistor 651, so the transistor 651 is turned off and no current flows between the collector terminal and the emitter terminal of the transistor 651. In this case, the voltage of the collector terminal of the transistor 651 becomes high level, and the high level voltage signal is output to the medal count control board 443 as the output signal of the break detection circuit 650.

Therefore, when the above-mentioned disconnection detection circuit 650 is provided, the medal count control board 443 can detect the presence or absence of a disconnection in the BRQ signal line based on the output signal input from the disconnection detection circuit 650 (information on the on/off state of the transistor 651 (the presence or absence of a current flowing between the collector terminal and the emitter terminal)). Specifically, when the level of the output signal input from the disconnection detection circuit 650 is low, the medal count control board 443 determines that the BRQ signal line is not disconnected, and when the level of the output signal input from the disconnection detection circuit 650 is high, the medal count control board 443 determines that the BRQ signal line is disconnected. Then, when it is determined that the BRQ signal line is disconnected, the medal count control board 443 performs control to stop operations such as the payout, lending, and settlement of game media.

The configuration of the mechanism for detecting the connection state (presence or absence of connection) between the medal count control board 443 and the game media lending device 402 is not limited to the above example. For example, in the medal count control board 443, the logical product of the output signal of the disconnection detection circuit 650 and the VL signal may be calculated, and the connection state (presence or absence of connection) between the medal count control board 443 and the game media lending device 402 may be detected based on the result of the calculation. In such a configuration, if at least one of the VL signal and the output signal of the transistor 651 is in the off state, it is determined that there is a possibility of a disconnection occurring between the medal count control board 443 and the game media lending device 402.

In addition, in the above-mentioned detection mechanism for the connection state (presence or absence of connection) using the output signal of the disconnection detection circuit 650 and the VL signal, it is necessary to perform a logical AND operation between the output signal of the disconnection detection circuit 650 and the VL signal input to the medal count control board 443, but this logical AND operation may be performed on software or may be configured with hardware. In the latter case, an AND circuit may be further provided, the VL signal is input to one input terminal of the AND circuit, the output signal of the disconnection detection circuit 650 is input to the other input terminal, and the operation result (output signal) of the AND circuit is input to the input terminal of the VL signal of the medal count control board 443 or the input terminal of the output signal of the disconnection detection circuit 650. In such a detection mechanism for the connection state (presence or absence of connection) using the output signal of the disconnection detection circuit 650 and the VL signal, if an error (such as a disconnection of the BRQ signal line) occurs, the game is controlled not to start. However, if an abnormality (high level signal) occurs only in the output signal of the disconnection detection circuit 650 and the VL signal is normal, operations such as the payout of gaming media and settlement are stopped, but the game can be controlled so that it can continue.

In the example shown in FIG. 92, the disconnection detection circuit 650 is provided for the BRQ signal line, but the present invention is not limited to this. For example, the disconnection detection circuit 650 may be provided for any one of the PRDY signal line, the EXS signal line, and the BRDY signal, or the disconnection detection circuit 650 may be provided for each of multiple signal lines (including all signal lines) of the PRDY signal line, the EXS signal line, the BRDY signal, and the BRQ signal line.

In addition, even in a gaming system that employs various detection mechanisms for the connection status (connection or non-connection) between the medal count control board 443 and the gaming media lending device 402 as described in Variation 6, medal-less gaming machines can be introduced and operated with just a simple modification of the program, just like the gaming system 400. In addition, since a GPIO is used between the medal count control board 443 and the gaming media lending device 402, the connection status of the line (connection wiring section 645) between the two can be easily confirmed.

<Modification 7>
In variant example 7, an example is described in which the gaming system 400 and the gaming systems of the various variant examples described above further include a third-party management server installed in a third-party institution (such as a card company) other than the gaming store (amusement arcade).

(1) Configuration of the gaming system Fig. 93 shows a schematic configuration of the gaming system of this example, and an overview of the operation of transmitting and receiving authentication information and the authentication result between the component devices. In Fig. 93, the same components as those of the gaming system 400 shown in Fig. 39 are denoted by the same reference numerals.

As shown in FIG. 93, the gaming system 700 of this example is configured to include a pachislot 401, which is a medal-less gaming machine, a gaming medium lending device 402 (gaming medium management device), a management computer 701, and a third-party management server 702. Note that both the pachislot 401 and the gaming medium lending device 402 are similar to those described in the gaming system 400 and the various modified examples described above, so their description will be omitted here.

The management computer 701 is installed in an amusement arcade (game parlor) in which multiple slot machines 401 are installed, and is communicatively connected to multiple gaming media lending devices 402 in the amusement arcade via an encrypted LAN. The management computer 701 is also communicatively connected to a third-party management server 702 via a wide area network.

The third-party management server 702 is installed in a third-party institution other than the gaming facility (e.g., a card company that issues gaming cards) and is managed by that third-party institution.

(2) Verification Operation of Authentication Information Next, we will explain the operation of transmitting and receiving authentication information and the authentication result between devices performed when the slot machine 401 is started in the gaming system 700. Note that the "authentication information" referred to here is information transmitted when the slot machine 401 is started, and includes, for example, the chip individual number (unique ID) of the main control microprocessor 450 (main CPU 501) of the slot machine 401, the ROM code of the main ROM 502, the chip individual number (unique ID) of the medal count control microprocessor 460 (medal count control CPU 501), the ROM code of the medal count control ROM 502, the unique ID of the sub-CPU (not shown), the gaming machine manufacturer code, the security chip manufacturer code, the model code of the slot machine 401, and the like.

First, when the slot machine 401 is started, an authentication information request signal is sent from the slot machine 401 to the third-party management server 702 via the game medium lending device 402 and the management computer 701, and the third-party management server 702 authenticates the slot machine 401. Although not shown in the figure, at this time, the authentication information of the slot machine 401 is also sent together with the authentication information request signal.

Next, when the third-party management server 702 receives the authentication information request signal, it authenticates at least each piece of information (ID information, etc.) included in the received authentication information with the corresponding information (ID information, etc.) that has been pre-registered in the third-party management server 702, and transmits the result of the authentication (authentication result) to the pachinko slot machine 401 via the management computer 701 and the game medium lending device 402. At this time, the third-party management server 702 transmits an encryption key to the management computer 701 along with the authentication result. In this case, since the encryption key is transmitted as part of the authentication result, the management computer 701 is unable to recognize that the received information contains encryption key information, and security can be maintained.

Then, the management computer 701 transmits the received authentication result and encryption key to the gaming media lending device 402. The management computer 701 then transmits the received authentication result to the slot machine 401. If the authentication result received by the slot machine 401 from the gaming media lending device 402 is normal, the slot machine 401 is started.

<Other Modifications>
In the gaming system of the above embodiment and various modifications, a pachinko slot machine has been used as an example of a gaming machine, but the present invention is not limited to this. Of the various techniques of the present invention described in the above embodiment and various modifications, techniques other than those specific to pachinko slot machines can also be applied to gaming systems equipped with gaming machines called "pachinko," and similar effects can be obtained.

In addition, the gaming machine according to one embodiment of the present invention having the above configuration can also have the following configuration.

The "wait for response" process (for example, S1025 in FIG. 58) performed among various processes executed by the main control board 441 shown in FIG. 57 to FIG. 67 is a process of waiting for a response from the medal count control board 443, but it can also include a timeout judgment process that counts the timeout (determines whether a certain period of time has elapsed without a response) until a response is received, or a numerical judgment process that determines whether an impossible value (information) is included in the command ("Ack command" or "Nack" command) from the medal count control board 443 when a response is received. In such a configuration, when the main CPU 501 detects an abnormality by the timeout judgment process and/or the numerical judgment process, it sets the state to an error state, displays an error code on the two-digit seven-segment LED for payout display in the game information display unit 426a (see FIG. 37A), and transmits an error command corresponding to the displayed error code to the sub-control board 442.

In the above embodiment, a configuration example has been described in which the medal count clear sound is output (sounded) when the medal count clear switch 443a is pressed, but the error sound and medal count clear sound may be sounded simultaneously. In such a configuration, when the medal count clear sound is sounded while the error sound is being sounded, if the error sound is a sound effect (such as a warning sound that is not a human voice), the medal count clear sound is a voice message, and conversely, if the error sound is a voice message, the medal count clear sound is a sound effect. In addition, in such a configuration, when the error sound is sounded at maximum volume, the medal count clear sound may be sounded at a volume one step lower, or the volume of the medal count clear sound may be set to a volume intermediate between the maximum volume (the volume of the error sound) and the volume set by the volume adjustment function.

In the above embodiment, an example was described in which the LED group 435 is used as a notification form for pressing the medal count clear switch 443a (clearing the medal count), but in addition, the display device 413 may also be used. In this case, a message or the like is displayed on the display screen of the display device 413 at a display position that does not obstruct the currently displayed display content, indicating that the medal count has been cleared, specifically, that the medal count (number of credits) displayed on the medal count display unit 426b (see FIG. 37B) has been cleared as a result of the medal count clear switch 443a being validly pressed.

In addition, in the above embodiment, the sub-CPU issues a medal count clear sound when it receives a setting change command (end) as received data, but the medal count clear sound may also be issued while the maintenance menu is being displayed. In this case, the LED group 435 may notify the player that the medal count has been cleared at the same time as issuing the medal count clear sound, or the display device 413 may notify the player that the medal count has been cleared, as described above.

[10-22. Supplementary notes]
Conventionally, so-called medalless gaming machines have been proposed in which gaming value is granted directly from a medal lending device (sand) without inserting medals, which are gaming media, into the gaming machine (see, for example, JP 2019-187818 A).

In the gaming machine described in JP 2019-187818 A, a payout control board that counts and controls the number of game values paid out is attached inside the cabinet, and the switches (buttons) connected to this payout control board include switches that can be operated by staff. Therefore, there is a demand for technology that can report information indicating whether such switches have been operated correctly.

The present invention was made in consideration of these points, and aims to provide a system for reporting information on whether or not a switch (button) connected to a board that controls the management of game value has been operated correctly in an amusement machine.

To achieve the above objective, the gaming machine according to this embodiment can provide a gaming machine having the following configuration:

A game control means (e.g., a main control microprocessor 450) for controlling the progress of the game;
A game value control means (e.g., a medal count control microprocessor 460) connected to the game control means and controlling management of the game value;
A game value display means (e.g., a medal count display unit 426b) connected to the game value control means and displaying information related to the game value;
A predetermined operation detection means (e.g., a medal count clear switch 443a) is connected to the game value control means and is capable of detecting a predetermined operation.
a game machine including a game device that is capable of updating information relating to a game value displayed on said game value display means when said predetermined operation is detected by said predetermined operation detection means;
In the gaming machine configured as described above, information regarding the game value displayed on the game value display means can be updated when a specified operation is detected, so that the operator can be notified of information indicating whether a specified operation (pressing operation) on the specified operation detection means (medal count clear switch 443a) was performed accurately.

In the gaming machine of the present invention, the information about the game value is the number of game values stored in the gaming machine,
When the power is turned on, if the predetermined operation is detected by the predetermined operation detection means, information relating to the game value displayed on the game value display means may be initialized.
In a gaming machine having the above-mentioned features, even if an unexpected error (abnormality) occurs in the control related to the management of the number of accumulated game values (number of credits), the number of accumulated game values can be initialized (cleared) by performing a predetermined operation on the predetermined operation detection means (medal number clear switch 443a), and the error can be easily cleared. Furthermore, when the above-mentioned feature is provided, the number of accumulated game values displayed on the game value display means is initialized by performing a predetermined operation on the predetermined operation detection means, so that a staff member of the gaming facility who performed the predetermined operation can easily recognize that the initialization operation (predetermined operation) of the number of accumulated game values has been performed accurately.

In the gaming machine of the present invention, a presentation control means (e.g., a sub-CPU) connected to the game control means for controlling presentations;
Further comprising: an audio output means (e.g., a speaker included in the speaker group 429) connected to the performance control means and outputting audio;
The game value control means notifies the game control means of a detection result by the predetermined operation detection means,
In a state where the predetermined operation is detected by the predetermined operation detection means, the game control means notifies the performance control means of predetermined information (e.g., a medal count clear start command) indicating that the predetermined operation is being performed,
The presentation control means may be configured to control the audio output means when the specified information is notified from the game control means, and to output a specified sound (e.g., a medal count clear sound) from the audio output means.
In a gaming machine having the above-mentioned features, for example, the fact that the accumulated number of game values has been cleared by a predetermined operation on the predetermined operation detection means (the medal count clear switch 443a) can be notified by the game value display means and also by the audio output means. Therefore, if the above-mentioned feature is provided, for example, when a staff member of an amusement facility performs a predetermined operation on the predetermined operation detection means, even if a situation occurs in which it is difficult to visually check the display on the game value display means, the staff member of the amusement facility can be reliably notified that a predetermined operation (valid operation) has been performed on the predetermined operation detection means.

In addition, in the gaming machine of the present invention, when the state where the predetermined operation is detected by the predetermined operation detection means is changed to a state where the predetermined operation is not detected, the game control means notifies the performance control means of specific information (for example, a medal count clear end command) indicating that the predetermined operation is not being performed,
The presentation control means may be configured to control the audio output means to stop output of the specified audio when the specific information is notified from the game control means and the specified audio is being output at that time.
In a gaming machine having the above-mentioned features, for example, the output of a predetermined sound (medal count clear sound) stops in conjunction with the completion of a predetermined operation on the predetermined operation detection means (medal count clear switch 443a), so that a situation does not occur in which the predetermined sound continues to sound even after the predetermined operation has been completed (after the process of clearing the stored number has been completed), thereby preventing the occurrence of an unpleasant situation.

In the gaming machine of the present invention, the output period of the predetermined sound may be set in advance.
In a gaming machine having the above-mentioned features, for example, even if the duration of a specified operation on the specified operation detection means (the duration of pressing the medal count clear switch 443a) becomes long, the output of the specified sound (medal count clear sound) stops at a predetermined output period, so that a situation in which the specified sound continues to sound for a long period of time does not occur, thereby preventing the occurrence of unpleasant situations.

In the gaming machine of the present invention, the game control means can execute a main control process that is repeated for each unit game and an interrupt process that is repeated at a predetermined cycle (for example, 1.1172 msec cycle),
The process by which the game control means receives notification of the detection result by the specified operation detection means from the game value control means, and the process of notifying the presentation control means of the specified information or the specific information corresponding to the detection result by the specified operation detection means, may be performed within the interrupt processing.
In a gaming machine having the above-mentioned features, for example, it is possible to perform a check process of the detection result by the predetermined operation detection means (for example, a medal count clear check process) during a setting change process.

In addition, the gaming machine of the present invention further includes a display means (e.g., a display device 413) that is connected to the performance control means and is capable of displaying information related to the game,
the display means is capable of displaying a menu screen including a plurality of selectable items;
The volume of the audio output means can be adjusted on the menu screen,
When the specified information is notified from the game control means to the presentation control means, if the menu screen is being displayed by the display means, the output operation of the specified sound by the sound output means is not performed, and the output operation of the specified sound is performed after the display of the menu screen has been completed.
In a gaming machine having the above-mentioned features, for example, a specified sound is output after a setting change operation or a setting confirmation operation is completed, so that an attendant at an amusement facility can remember to check (visually) that the accumulated number of gaming values displayed on the 7-segment LED has been cleared.

In the gaming machine of the present invention, the game value control means and the predetermined operation detection means are mounted on separate boards,
The predetermined operation on the predetermined operation detection means may be performed using a dedicated tool.
In a gaming machine having the above-mentioned features, for example, it is possible to prevent a predetermined operation (pressing operation) from being performed erroneously on a predetermined operation detection means (for example, the medal count clear switch 443a).

In addition, in the gaming machine of the present invention, the gaming value display means may have an error display means (for example, a single-digit 7-segment LED for error display within the medal count display unit 426b) that displays an error that has occurred in the control related to the management of the gaming value.
In a gaming machine having the above-mentioned characteristics, a display means dedicated to errors in the control related to the management of game value is provided, so that, for example, there is no confusion between errors in the control related to the management of game value and other errors, it is possible to easily recognize that an error in the control related to the management of game value has occurred, and it is also possible to easily decide how to resolve the error.

In the gaming machine of the present invention, the game value control means has a stored number counting means (e.g., a medal counter) for counting the number of stored game values,
When the game value is paid out, if the result of adding the number of paid out game values to the number of stored game values counted by the stored number counting means exceeds a first threshold value which is an upper limit value of the number of stored game values, progress of the game is stopped and the error display means notifies the user that the number of stored game values exceeds the first threshold value;
When the game value is paid out, if the result of adding the payout number of the game value to the stored number of game value counted by the stored number counting means exceeds a second threshold value that is less than the first threshold value of the stored number of game value, the progress of the game is not stopped, but the error display means may notify the user that the stored number of game value exceeds the second threshold value.
In a gaming machine having the above characteristics, when the result of adding the payout number of game values to the current number of saved game values exceeds a first threshold value (upper limit value), the progress of the game is stopped and the error display means notifies the player that the number of saved game values exceeds the first threshold value (upper limit value) (upper limit exceeding error), so that the player can be prompted to settle the saved game value. Also, in a gaming machine having the above characteristics, when the result of adding the payout number of game values to the current number of saved game values exceeds a second threshold value that is less than the first threshold value (upper limit value), the error display means notifies the player that the number of saved game values exceeds the second threshold value (upper limit exceeding notice error), but the progress of the game is not stopped in this case. Therefore, if a notification function is provided for an error (warning) notifying the player of an upper limit exceedance of the accumulated game value, the player can be urged to quickly settle the accumulated game value before an upper limit exceedance error occurs that would halt the progress of the game.In this case, the player can continue playing smoothly without halting the progress of the game.

The gaming machine of the present invention configured as described above can inform the operator of, for example, information indicating whether or not an operation on a switch (button) connected to a board that controls the management of gaming value has been performed correctly.

401... Pachislot, 402... Game media lending device, 413... Display device, 426a... Game information display unit, 426b... Medal count display unit, 427a... Medal lending display unit, 429... Speaker group, 441... Main control board, 442... Sub-control board, 443... Medal count control board, 443a... Medal count clear switch, 450... Main control microprocessor, 460... Medal count control microprocessor, 481... Main control board case, 482... Medal count control board case, 482a... Small hole

Claims (1)

A game control means for controlling the progress of a game;
a game value control means connected to the game control means and performing control related to management of the game value;
a game value display means connected to the game value control means and displaying information related to the game value;
a predetermined operation detection means connected to the game value control means and capable of detecting a predetermined operation;
A performance control means connected to the game control means for controlling the performance;
an audio output means connected to the performance control means and configured to output audio;
A display means connected to the performance control means and capable of displaying information related to a game ,
When the predetermined operation is detected by the predetermined operation detection means, information about the game value displayed on the game value display means can be updated;
the game value control means notifies the game control means of a detection result by the predetermined operation detection means,
In a state where the predetermined operation is detected by the predetermined operation detection means, the game control means notifies the performance control means of predetermined information indicating that the predetermined operation is being performed;
When the predetermined operation detection means detects the predetermined operation and then transitions to a state where the predetermined operation is not detected, the game control means notifies the performance control means of specific information indicating that the predetermined operation is not being performed;
the presentation control means, when notified of the predetermined information by the game control means, controls the sound output means to output a predetermined sound from the sound output means;
the display means is capable of displaying a menu screen including a plurality of selectable items;
The volume of the audio output means can be adjusted on the menu screen,
When the game control means notifies the performance control means of the predetermined information, if the menu screen is being displayed by the display means, the audio output means does not output the predetermined sound, and the audio output means outputs the predetermined sound after the display of the menu screen is completed.
the performance control means is capable of controlling the sound output means to stop output of the predetermined sound when the specific information is notified from the game control means and the predetermined sound is being output at that time;
The game control means is capable of executing a main control process which is repeated for each unit game and an interrupt process which is repeated at a predetermined cycle;
The processing by the game control means to receive a notification of the detection result by the predetermined operation detection means from the game value control means and the processing to notify the performance control means of the predetermined information or the specific information corresponding to the detection result by the predetermined operation detection means are performed in the interrupt processing.
A gaming machine characterized by:

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