JP7112543B2 - game machine - Google Patents

Description

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

Conventionally, a plurality of reels each having a plurality of patterns arranged on its surface and game medals, coins, etc. (hereinafter referred to as "medals, etc.") are inserted, and it is detected that the start lever has been operated by the player, A start switch requesting the start of rotation of a plurality of reels and a stop button provided corresponding to each of the plurality of reels are detected to be pressed by the player, and requests to stop the rotation of the relevant reels. a stop switch that outputs a signal; a stepping motor that is provided corresponding to each of a plurality of reels and transmits the respective driving force to each reel; and a reel control unit that rotates and stops each reel, and when it detects that the start lever has been operated, a lottery is performed based on a random number value, and the result of this lottery (hereinafter referred to as " A so-called pachislot machine is known that stops the rotation of the reels based on the timing of detecting that the stop button has been operated.

In this type of game machine, when executing a sound effect using a speaker for a player during a game and an effect of making the game machine emit light using a light emitting member such as an LED, the sound to be reproduced is determined. A game machine is already known that determines an effect to make the game machine emit light in response to the event (see, for example, Patent Document 1).

In such a gaming machine, a variety of effects can be executed by executing a lighting effect of the game machine at the same time as a sound effect. can.

JP 2008-295553 A

SUMMARY OF THE INVENTION An object of the present invention is to provide a game machine capable of enhancing the interest of a game by appropriately controlling lock effects and sound output.

In order to achieve the above object, the gaming machine according to the present invention includes a variable display section capable of variably displaying a plurality of pieces of identification information in a plurality of display columns, and the variable display section starts and then stops variably displaying the information. A gaming machine capable of deriving a display and providing a privilege according to the display of the result, comprising a start operation detection means capable of detecting a game start operation and a specific combination (bonus reply 1, bonus reply 2) that cannot be carried over. a winning combination determining means capable of determining a winning combination from among a plurality of winning combinations including; a stop operation detecting means capable of detecting a stop operation for stopping the variable display of the variable display section; stop control means for stopping the variable display of the variable display unit according to the winning combination and the stop operation mode detected by the stop operation detection means; State control means capable of controlling the state, and when the specific result display corresponding to the specific combination is derived in the lock waiting state (ART start waiting state) after being notified of the transition to the specific game state. lock execution means for performing a lock (effect lock) for delaying the progress of the game for a predetermined period; sound output means capable of outputting sound; sound data storage means for storing sound data; and outputting the sound data. a channel determining means capable of determining a channel according to the gaming state when the player is in the lock waiting state; It is possible to execute a promotion effect to prompt a stop operation in a specific mode from which a specific result display can be derived, and the specific result display is performed when the specific combination is determined as a winning combination by the combination determining means. Even if the stop operation is performed according to, it is configured so that it may not be derived depending on the timing of the stop operation, and the specific game state is derived from the specific result display in the lock waiting state. It is started after the lock is executed, and is not started if the specific result display is not derived and the lock is not executed, and the specific combination is determined by the combination determination means to be the winning combination in the lock waiting state. Even if it is determined as, if the specific result indication is not derived and the lock is not executed, the lock waiting state can be maintained until the specific result indication is derived and the lock is executed. , the sound data corresponding to the promotion effect is output from the first channel, and the start operation detecting means detects the start operation; The sound data of the game start sound corresponding to the detection is output from the second channel, and the sound data corresponding to the background music during the specific game state is output from the third channel .

Further, the gaming machine according to the present embodiment includes variable display units (reels 3L, 3C, 3R) capable of variably displaying identification information (symbols of reels 3L, 3C, 3R). A gaming machine capable of deriving a result display (combination of symbols) by stopping the game after starting the game, and granting benefits (payout of medals, activation of replay, activation of bonus, etc.) according to the result display. , a winning combination determination means (main CPU 31) capable of determining a winning combination from among a plurality of combinations including a specific combination, and a stop operation detecting means (stop button 7L, 7C, 7R, stop switch 7S), the winning combination determined by the combination determination means, and the stop operation mode detected by the stop operation detection means, stopping the variable display of the variable display unit. stop control means (motor drive circuit 38, stepping motors 49L, 49C, 49R), and when a predetermined condition is satisfied, a lock wait state is set, and the unit game following the unit game in which the predetermined condition is satisfied. a specific lock executing means (main CPU 31) for performing a specific lock (starting lock) that disables the game operation by the player for a predetermined period when the result display corresponding to the specific combination is derived in the lock waiting state; Special lock determination means (main CPU 31) capable of determining whether to perform a special lock (long freeze) different from the specific lock in a unit game in which a predetermined condition is established Special lock execution means (main CPU 31) for executing the special lock in the unit game in which the predetermined condition is established when it is determined to execute the lock, and effect execution means (for executing the predetermined effect) Dot display device 100 (LED), speakers 9L, 9R) and effect determination means (sub CPU 81, LED / sound output list table) capable of determining effect data related to effect executed by the effect execution means, The effect executing means can preferentially execute the effect corresponding to the new effect data when the new effect data is determined by the effect determining means during execution of the effect corresponding to the predetermined effect data. , as the effect data determinable by the effect determining means, first effect data (hibiscus lighting data at the time of BB winning) related to the effect to be executed when the result display corresponding to the specific role is derived; After deriving the corresponding result representation and second effect data (hibiscus lamp lighting data during BB) relating to the effect to be executed during the specific game state that occurs, and the predetermined condition is that the winning combination determined by the combination determination means is the specified combination. The specific combination can be established in a unit game in which a winning combination (watermelon, Kakucherry, etc.) is different from the combination (BB Rip, RB Rip), and indicates that the specific combination has been determined as the winning combination by the combination determining means. The winning combination information of the combination is a first game state (pseudo RB) that is advantageous to the player as a game state that cannot be carried over to the next unit game and can be started after the specific lock is executed, and the first game. There is a second game state (pseudo BB) that is more advantageous to the player than the state, and when the special lock is executed in the unit game in which the predetermined condition is established, the game is started after the subsequent specific lock is executed. The game state to be played is the second game state.
With this configuration, the gaming machine according to the present embodiment executes an effect at a timing that matches the occurrence of a specific lock (winning a BB reply), and after that, the state is switched (during pseudo BB) and the next effect is executed. When it becomes a situation where it should be, it is possible to smoothly switch the production.

In addition, in the gaming machine according to the present embodiment, the effect execution means includes a plurality of effect execution units (dot display device 100, light emitting unit 330, reel effect display device 103), and the effect data as the effect data. It has effect data including information (information related to the "target part" in the LED/sound output list table) that can specify the effect execution unit that executes the corresponding effect, and has a plurality of different probabilities that the predetermined condition is satisfied a first random value extraction means capable of extracting a first random value from a first range; and a second random value capable of extracting a second random value from a second range. a numerical value extracting means, wherein the winning combination is determined by the combination determination means using the first random value, and the mode transition determination by the mode control means is performed using the second random value. It is configured.
With this configuration, the gaming machine according to the present embodiment associates the location where the effect is generated with the data (light emission pattern) to make it unified information (see the LED/sound output list table in FIG. 64). It is possible to reduce the number of tables and the processing load, and to that extent, it is possible to increase the variation of effects when a lock occurs.

In addition, the gaming machine according to the present embodiment includes a plurality of peripheral devices (speakers 9L, 9R, dot display device 100, reel effect display device 103, re-effect display device 104) related to performance, and a plurality of performance information (sound data , LED effect data) stored effect information storage means (sub ROM 82), effect control means (sub CPU 81) connected to the plurality of peripheral devices and performing control related to effect, and from the plurality of effect information Effect information determining means (sub CPU 81) for determining effect information; Effect information executing means (sub CPU 81, DSP 84) for executing the effect information determined by the effect information determining means; contains first effect information (sound data) and second effect information (LED effect data) each composed of a plurality of said effect information, and said second effect information is at least said effect information is associated with the first effect information, target parts of the plurality of peripheral devices are set (FIG. 64), and the effect information executing means performs effect according to the first effect information. A first effect information executing means (DSP 84) for execution and a second effect information executing means (sub CPU 81) for executing effects according to the second effect information, wherein the first effect information executing means and the second effect information execution means includes a configuration capable of executing the first effect information and the second effect information by any of the plurality of peripheral devices, and an execution state of the first effect information ( sound reproduction state) and the execution state of the second effect information (LED control state information), and the effect control means is such that the first effect execution means executes the first effect information If so, the first effect information updating means (sub CPU 81) for updating the state information of the first effect information being executed, and the second effect executing means execute the second effect information. second effect information updating means (sub CPU 81) for updating the state information of the second effect information being executed, and the second effect updated by the second effect information updating means a performance information determination means (sub CPU 81) for determining whether or not the second performance information execution means is executing the second performance state based on the state information of the information; and the performance control means. is, when the effect information determining means determines that the second effect information executing means is not executing the second effect information, the first effect information updating means When it is determined that the first effect information execution means is executing the first effect information from the state information of the first effect information updated by the above, the second effect information execution means sends the The second effect information associated with the first effect information is executed.
With this configuration, in the gaming machine according to the present embodiment, the second effect information is associated with the first effect information, the first effect information is being executed, and the first effect information being executed When the second performance information associated with the performance information is not executed, the associated second performance information is transferred from the performance information storage means to the performance information execution means and executed. Therefore, it is possible to suppress the occurrence of bugs with a simple configuration and prevent an increase in design man-hours.

According to the present invention, the amusement of the game can be enhanced.

It is a diagram showing a functional flow of the pachi-slot machine according to the embodiment of the present invention. 1 is an overall perspective view showing an external structure of a pachi-slot machine according to an embodiment of the present invention; FIG. 1 is a front view of a pachi-slot machine according to an embodiment of the present invention with a front panel removed; FIG. 1 is a front view of the inside of a cabinet of a pachi-slot machine according to an embodiment of the present invention; FIG. 1 is an exploded detailed view of a reel of a pachi-slot machine according to an embodiment of the present invention; FIG. It is a diagram showing the configuration of the front panel of the pachi-slot machine according to the embodiment of the present invention. It is a diagram showing a configuration of a reel lower display device of the pachi-slot machine according to the embodiment of the present invention. 1 is a block diagram showing the configuration of a main control circuit of a pachi-slot machine according to an embodiment of the present invention; FIG. 1 is a wiring configuration diagram of an external centralized terminal board of a pachi-slot machine according to an embodiment of the present invention; FIG. 2 is a block diagram showing the configuration of a sub-control circuit of the pachi-slot machine according to the embodiment of the present invention; FIG. It is a transition diagram of the main game state in the pachi-slot machine according to the embodiment of the present invention. It is a transition diagram of the ART game state in the pachi-slot machine according to the embodiment of the present invention. It is a figure which shows the pattern arrangement|positioning table memorize|stored in main ROM. It is a figure which shows the design code table|surface memorize|stored in main ROM. It is a figure which shows the symbol combination table (bonus) memorize|stored in main ROM. It is a figure which shows the design combination table (replay) memorize|stored in main ROM. It is a figure which shows the symbol combination table (minor combination) memorize|stored in main ROM. It is a figure which shows the internal lottery table for normal game states memorize|stored in main ROM. FIG. 10 is a diagram showing an internal winning combination determination table for the RT1 gaming state stored in the main ROM; FIG. 10 is a diagram showing an internal winning combination determination table for minor winning combination/replay stored in the main ROM; FIG. 10 is a diagram showing an internal winning combination determination table for bonus stored in the main ROM; FIG. 10 is a diagram showing a reel stop initial setting table stored in a main ROM; It is a figure which shows the attraction priority table selection table memorize|stored in main ROM. It is a figure which shows the attraction priority table memorize|stored in main ROM. FIG. 4 is a diagram showing a priority order table stored in a main ROM; FIG. It is a figure which shows the priority order table for MB game states memorize|stored in main ROM. FIG. 11 is a relational diagram between an internal winning combination and a winning combination according to the stop operation order. FIG. 10 is a diagram showing an internal winning combination storage area stored in the main ROM; FIG. 10 is a diagram showing a display combination storing area stored in a main ROM; It is a figure which shows the pattern code storage area memorize|stored in main ROM. FIG. 4 is a diagram showing an operation stop button storage area stored in a main ROM; FIG. 10 is a diagram showing a pressing order storage area stored in a main ROM; FIG. 10 is a diagram showing a carryover combination storing area stored in a main ROM; It is a figure which shows the game state flag storage area memorize|stored in main ROM. It is a figure which shows the attraction priority data storage area memorize|stored in main ROM. It is an explanatory diagram of the outline of each mode to stay in the ART game state. FIG. 10 is a diagram showing a mode transition lottery table in mode 1 stored in the main ROM; FIG. 10 is a diagram showing a mode transition lottery table in mode 2 stored in the main ROM; FIG. 10 is a diagram showing a mode transition lottery table in mode 3 stored in the main ROM; FIG. 10 is a diagram showing a mode transition lottery table in mode 4 stored in the main ROM; FIG. 10 is a diagram showing a mode transition lottery table in mode 5 stored in the main ROM; FIG. 10 is a diagram showing a mode transition lottery table in mode 6 stored in the main ROM; FIG. 10 is a diagram showing a mode transition lottery table in mode 7 stored in the main ROM; FIG. 10 is a diagram showing a mode transition lottery table in mode 8 stored in the main ROM; FIG. 10 is a diagram showing a mode transition lottery table in mode 9 stored in the main ROM; FIG. 10 is a diagram showing a unlocked game number lottery table in mode 1 stored in the main ROM; FIG. 10 is a diagram showing a number-of-released-games lottery table in mode 2 stored in the main ROM; FIG. 10 is a diagram showing a number-of-released-games lottery table in mode 3 stored in the main ROM; FIG. 10 is a diagram showing a unlocked game number lottery table in mode 4 stored in the main ROM; FIG. 10 is a diagram showing a unlocked game number lottery table for modes 5 to 7 stored in the main ROM; FIG. 10 is a diagram showing a unlocked game number lottery table in mode 8 stored in the main ROM; It is a figure which shows the release lottery table memorize|stored in main ROM. It is a figure which shows the short freeze lottery table at the time of ART winning state transition memorize|stored in main ROM. It is a figure which shows the long freeze reservation lottery table at the time of ART winning state transition memorize|stored in main ROM. It is a figure which shows the announcement mode lottery table at the time of ART winning state transition memorize|stored in main ROM. It is a figure which shows the long freeze reservation lottery table during ART memorize|stored in main ROM. FIG. 10 is a diagram showing an ART type notification distribution lottery table stored in a sub-ROM; It is a figure which shows the normal navigation lottery table memorize|stored in sub ROM. It is a figure which shows the special navigation lottery table memorize|stored in sub ROM. It is a figure which shows the dishonest navigation lottery table memorize|stored in sub ROM. FIG. 4 is a diagram showing a sound list table stored in a sub ROM; FIG. FIG. 4 is a diagram showing a sound list table stored in a sub ROM; FIG. FIG. 4 is a diagram showing a sound sequence table stored in a sub ROM; FIG. FIG. 10 is a diagram showing an LED/sound output list table stored in a sub-ROM; 4 is a flow chart showing main control processing of the pachi-slot machine according to the embodiment of the present invention; FIG. 66 is a flowchart showing power-on processing executed in the main control processing shown in FIG. 65; FIG. FIG. 66 is a flow chart showing a medal acceptance/start check process executed in the main control process shown in FIG. 65; FIG. FIG. 66 is a flow chart showing an internal lottery process executed in the main control process shown in FIG. 65; FIG. FIG. 66 is a flowchart showing an ART gaming state lottery process executed in the main control process shown in FIG. 65; FIG. FIG. 70 is a flowchart showing an ART-playing process executed in the ART-game state lottery process shown in FIG. 69; FIG. FIG. 70 is a flowchart showing an ART winning state process executed in the ART gaming state lottery process shown in FIG. 69; FIG. 70 is a flowchart showing ART winning state transition processing executed in the ART gaming state lottery processing shown in FIG. 69; FIG. 66 is a flowchart showing a reel stop initialization process executed in the main control process shown in FIG. 65; FIG. FIG. 66 is a flow chart showing freeze processing at game start executed in the main control processing shown in FIG. 65; FIG. FIG. 79 is a flow chart showing an attraction priority storing process executed in the main control process shown in FIG. 65 and the reel stop control process shown in FIG. 78; FIG. FIG. 76 is a flow chart showing a pattern code storing process executed in the attraction priority storing process shown in FIG. 75; FIG. FIG. 76 is a flow chart showing attraction priority table selection processing executed in the attraction priority storage processing shown in FIG. 75; FIG. FIG. 66 is a flow chart showing a reel stop control process executed in the main control process shown in FIG. 65; FIG. FIG. 79 is a flow chart showing a priority pull-in control process executed in the reel stop control process shown in FIG. 78; FIG. FIG. 66 is a flowchart showing ART-related processing executed in the main control processing shown in FIG. 65; FIG. FIG. 66 is a flow chart showing lock processing at the time of game end executed in the main control processing shown in FIG. 65; FIG. FIG. 66 is a flow chart showing a bonus end check process executed in the main control process shown in FIG. 65; FIG. FIG. 66 is a flow chart showing bonus operation check processing executed in the main control processing shown in FIG. 65; FIG. 4 is a flow chart showing interrupt processing under control of a main CPU that constitutes the pachi-slot machine according to the embodiment of the present invention. 85 is a flow chart showing input port check processing executed in the interrupt processing shown in FIG. 84; FIG. 85 is a flow chart showing communication data transmission processing executed in the interrupt processing shown in FIG. 84; FIG. 4 is a flow chart showing power-on processing of a sub CPU constituting the pachi-slot machine according to the embodiment of the present invention. FIG. 88 is a flow chart showing a mother task activated in the power-on process shown in FIG. 87; FIG. 88 is a flowchart showing an LED output control task activated in the power-on process shown in FIG. 87; FIG. 90 is a flowchart showing LED output data analysis processing executed in the LED output control task shown in FIG. 89; FIG. FIG. 90 is a flowchart showing LED output control execution processing executed in the LED output control task shown in FIG. 89; FIG. FIG. 88 is a flow chart showing a sound control task activated in the power-on process shown in FIG. 87; FIG. FIG. 93 is a flow chart showing initialization processing of sound-related data executed in the sound control task shown in FIG. 92; FIG. FIG. 93 is a flow chart showing sound data analysis processing executed in the sound control task shown in FIG. 92; FIG. FIG. 93 is a flowchart showing sound effect execution processing executed in the sound control task shown in FIG. 92; FIG. 89 is a flow chart showing a main board communication task activated in the mother task shown in FIG. 88; FIG. 97 is a flow chart showing received command check processing executed in the main control board task shown in FIG. 96; FIG. FIG. 97 is a flow chart showing command analysis processing executed in the main board communication task shown in FIG. 96; FIG. FIG. 99 is a flow chart showing effect content determination processing executed in the command analysis processing shown in FIG. 98; FIG. 99. It is a flowchart which shows the process at the time of start command reception performed in the content determination process of production|presentation shown in FIG. 99. It is a flowchart which shows the process at the time of start command reception performed in the content determination process of production|presentation shown in FIG. FIG. 100 is a flow chart showing a winning actuation command reception process executed in the effect content determination process shown in FIG. 99; FIG. FIG. 10 is a perspective view showing the appearance of a gaming machine according to another embodiment of the present invention; FIG. 10 is a front view showing a schematic configuration of a game board of a game machine according to another embodiment of the present invention; It is a block diagram showing the configuration of the main control circuit and the sub-control circuit of the game machine in another embodiment of the present invention.

A pachi-slot machine, which is an example of the gaming machine according to the present invention, will be described below with reference to the drawings.

[Function Flow of Pachislot Machine]
As shown in FIG. 1, when a player inserts medals into the pachi-slot machine 1 and operates the start lever 6, one value is selected from a predetermined numerical range (for example, 0 to 65535). (hereafter, random number) is extracted.

An internal winning combination determining means (main CPU 31, which will be described later) performs a lottery based on the extracted random number value to determine an internal winning combination. That is, the winning combination determination means selects an internal game from a plurality of combinations with a predetermined probability based on the detection of the start operation of the unit game with respect to the start lever 6 by the start switch 6S (see FIG. 8) (the establishment of a predetermined start condition). Determine the winning combination.

By determining the internal winning combination, the combination of symbols that are permitted to be displayed along the winning line, which will be described later, is determined. As for the type of combination of symbols, there are two types of combinations: medal payout, replay activation, bonus activation, etc. There are related items.

Subsequently, after the plurality of reels 3L, 3C, and 3R are rotated, when the player presses the stop buttons 7L, 7C, and 7R, the reel stop control means (motor drive circuit 39 described later, stepping The motors 49L, 49C, 49R) perform control to stop rotation of the corresponding reels 3L, 3C, 3R based on the internal winning combination and the timing at which the stop buttons 7L, 7C, 7R are pressed.

Here, in the pachi-slot machine 1, basically, control is performed to stop the rotation of the relevant reels 3L, 3C, 3R within a specified time (190 msec) from when the stop buttons 7L, 7C, 7R are pressed. . In the present embodiment, the number of symbols that move with the rotation of the reels 3L, 3C, and 3R within the specified time is called "the number of sliding symbols", and the maximum number is four symbols (maximum number of sliding symbols). ).

However, in the MB (accessory continuous actuating device pertaining to the second type special accessory) gaming state, the relevant reel within 75 ms, which is the prescribed time from when at least one stop button among the plurality of stop buttons is pressed, is controlled to stop the rotation of

When an internal winning combination permitting the display of a winning symbol combination is determined, the reel stop control means utilizes the specified time to display the symbol combination along the winning line as an active line. The rotation of the reels 3L, 3C, and 3R is stopped within the range of the maximum number of sliding symbols so as to be displayed as much as possible.

On the other hand, for combinations of symbols whose display is not permitted by internal winning combinations, reels are displayed within the range of the maximum number of sliding symbols so as not to be displayed along the winning line using the above-mentioned stipulated time. Stop rotation of 3L, 3C, and 3R.

In this way, when all of the plurality of reels 3L, 3C, and 3R stop rotating, the winning determination means (main CPU 31, which will be described later) determines whether the combination of symbols displayed along the winning line is related to winning. A determination is made as to whether or not

That is, the winning determination means determines whether a combination is established (winning) or not established (non-winning) based on the combination of symbols stopped on the winning line based on the stop of the fluctuation of the symbols by the reel stop control means. do.

When it is determined that the game is related to winning a prize, a privilege such as payout of medals is given to the player. A series of flows as described above are performed as one game (unit game) in the pachi-slot machine 1 .

In the present embodiment, the reel stop operation (operation of the stop buttons 7L, 7C, 7R) performed first when all the reels 3L, 3C, 3R are rotating is the first stop operation, and the first A stop operation that follows the stop operation is called a second stop operation, and a stop operation that follows the second stop operation is called a third stop operation.

Further, in the pachi-slot machine 1, in the above-described series of flows, light output by the effect executing means (the dot display device 100 and the front panel 110), sound output by the speakers 9L and 9R, or a combination of these Various productions are performed using it.

When the player operates the start lever 6, in addition to the random number used to determine the internal winning combination, a random number used for other lottery processing, such as a mode transition lottery during the RT1 game state to be described later, is generated. Numerical values and random numbers for effects (hereinafter referred to as random numbers for effects) are extracted.

When the random number value for effect is extracted, the effect content determination means (sub CPU 81 described later) determines by lottery the effect content to be executed this time out of the plurality of types of effect contents associated with the internal winning combination.

When the content of the effect is determined, the effect executing means determines whether or not there is a prize when the reels 3L, 3C and 3R start rotating and when the reels 3L, 3C and 3R stop rotating. Proceed with the execution of the production in conjunction with each opportunity such as when it is broken.

In this way, the pachi-slot machine 1 provides the player with an opportunity to know or predict the determined internal winning combination (in other words, the combination of symbols to aim for) by executing the performance contents associated with the internal winning combination. to improve the interest of the player.

In particular, in the pachi-slot machine 1, a dot display 100 consisting of a plurality of LEDs and a front panel 110 arranged in front of the dot display 100 are used to perform various effects. Here, the front panel 110 has an arbitrary design on the player's side, and is configured so that light from the LEDs of the dot display device 100 can be transmitted through part or all of the front panel 110 .

In the pachi-slot machine 1, the effect control means (sub CPU 81, which will be described later) performs lighting control (lighting, blinking, extinguishing) of the dot indicator 100 (LED) according to a predetermined program, and the design applied to the front panel 110 is changed. By lighting, various productions are performed.

In addition, in the pachi-slot machine 1, by changing the front panel 110 arranged in front of the dot display device 100 and changing the control data for controlling the dot display device 100, there is no need to change the housing. It is also possible to perform different productions.

[Pachislot structure]
The functional flow of the pachi-slot machine 1 has been described above. Next, the structure of the pachi-slot machine 1 according to the present embodiment will be described with reference to FIGS. 2 to 6. FIG.

FIG. 2 is a perspective view of the pachi-slot machine 1 according to this embodiment. FIG. 3 is a front view of the pachi-slot machine 1 according to the present embodiment with the protective panel 5 removed. FIG. 4 is a front view of the inside of the cabinet of the pachi-slot machine 1 according to this embodiment. FIG. 5 is an exploded detailed view of the reels 3L, 3C and 3R of the pachi-slot machine 1 according to this embodiment.

The pachi-slot machine 1 is a gaming machine in which games are played using game media such as coins, medals, game balls, tokens, etc., as well as cards storing information on game values given or given to players. However, in the following description, it is assumed that medals are used.

A housing 4 forming the entire Pachi-slot machine 1 includes a box-shaped cabinet 60 and a front door 2 for opening and closing the cabinet 60. - 特許庁A reel upper display 101 is provided at the front uppermost portion of the front door 2 . A transparent protection panel 5 is provided substantially in the center of the front face of the front door 2, and a reel effect display 103 and a side effect display 104 are provided on the left and right sides of the protection panel 5. - 特許庁

Further, inside the protective panel 5, as shown in FIG. 3, a dot display 100 having a plurality of light-emitting diodes (LEDs) arranged in a horizontally long rectangular shape is provided substantially in the upper part of the center. Between the dot display 100 and the protective panel 5, a horizontally long rectangular front panel 110 shown in FIG. 6 is arranged.

As shown in FIG. 6, the front panel 110 is configured so that light from the LEDs of the dot display device 100 can be transmitted through part or all of the front panel 110, and a design imitating a pair of hibiscus patterns is applied to the front side of the panel. there is

The hibiscus pattern is given a predetermined color and illuminated from the dot display device 100 to constitute the notification section 111 for notifying the player of predetermined information through the transparent protective panel 5 .

Predetermined information notified by the notification unit 111 is locked (for example, locked at start described later) when "bonus reply 1" or "bonus reply 2" is won during the ART winning state described later. ART winning announcement (hereinafter also simply referred to as “winning announcement”) to the effect that it has been decided. In this manner, the notification unit 111 constitutes notification means in cooperation with the sub CPU 81, which will be described later.

For example, the notification unit 111 notifies the player that ART, which will be described later, is in an operable state. That is, the notification unit 111 is for performing an ART winning notification, which will be described later, to the player.

Note that the design of the front panel 110 shown in FIG. 6 is an example, and the design of the front panel 110 can be changed as appropriate. By changing the design of the front panel 110, it becomes possible to inform the player of completely different information, and to perform various effects.

Further, in the present embodiment, the front panel 110 arranged between the dot display 100 and the protective panel 5 is used for the effect using the dot display 100, but this is not the only option. By applying a predetermined design to a sheet and attaching the sheet to the front surface (or back surface) of the front panel 110, an effect using the dot display device 100 may be performed.

Returning to FIG. 3, the dot display device 100 is configured by arranging a plurality of LEDs at regular intervals in a horizontally long rectangular shape substantially identical to the shape of the front panel 110 . The dot display device 100 lights (blinks) an LED at an arbitrary location to illuminate an arbitrary location of the design applied to the front panel 110 (in this embodiment, the hibiscus design notification section 111) from the back. .

A reel illuminator 102 is provided below the dot display 100 . In this embodiment, the dot display device 100, the reel upper display device 101, the reel lighting device 102, the reel effect display device 103, and the side effect display device 104 are made to emit light using light emitting diodes (LEDs), but organic electroluminescence is used. Existing light-emitting elements such as (organic EL) can be used as long as they can emit light in at least green, yellow, blue, and red.

Vertically long rectangular display windows 4L, 4C, and 4R constituting pattern display means are provided below the reel illuminators 102 . The display windows 4L, 4C, and 4R display an upward-sloping cross-up line 8a, an upper top line 8b, a middle center line 8c, a lower bottom line 8d, and a downward-sloping cross-down line 8e. .

In the present embodiment, among these lines 8a to 8e, only the center line 8c in the middle is a winning line, and the other lines 8a, 8b, 8d, and 8e may display a combination of symbols related to a winning combination. It is just a display line that does not count as winning.

Therefore, the center line 8c is also called the winning line 8c, and the other lines 8a, 8b, 8d and 8e are also called the display lines 8a, 8b, 8d and 8e, respectively. The winning line 8 c is activated by operating a bet button 11 (hereinafter referred to as “BET operation”) or inserting medals into the medal slot 22 .

Below the display windows 4L, 4C and 4R, reel lower display devices 105 for displaying information about games played in the pachi-slot machine 1 are provided. The reel lower display 105 is provided with three digital display sections 105L, 105C, and 105R.

These digital display sections 105L, 105C and 105R are provided corresponding to the reels 3L, 3C and 3R, respectively, and inform the order of stopping the corresponding reels. In this manner, the reel lower display 105 constitutes stop operation notification means in cooperation with the sub CPU 81, which will be described later.

For example, in the example shown in FIG. 7, it is notified that the reel 3C is to be operated for the first stop, the reel 3R is operated for the second stop, and the reel 3L is operated for the third stop. The player can win a specific small combination (for example, middle bell = 9 pieces) by operating the stop button in the order of the stop operations notified on the reel lower display 105 during the ART game state, which will be described later. can.

A substantially horizontal pedestal 10 is formed below the reel lower display 105 .
In the horizontal plane of the pedestal 10, a medal slot 22 is provided on the right side, an information display 13 for mainly displaying information on the number of medals is provided substantially in the center, and a bet button 11 is provided on the left side. . Inside the bet button 11, there is provided a bet button LED 108 (see FIG. 8) that lights up when medals can be inserted.

By pressing this bet button 11, the number of medals used for one unit game (one game) is inserted, and as described above, the winning line 8c is activated. The operation of the bet button 11 and the operation of inserting medals into the medal slot 22 (the operation of inserting medals for playing a game) are hereinafter referred to as "BET operation".

The information display 13 is provided with an LED (not shown) that lights up corresponding to the number of medals inserted in the current game (hereinafter referred to as the inserted number). The information display device 13 also displays information such as the number of medals to be paid out to the player as a privilege (hereinafter referred to as the number of payouts) and the number of medals deposited inside the pachi-slot machine 1 (hereinafter referred to as the number of credits). A digital display (not shown) is provided for digital display to the player.

Further, the information display 13 digitally displays an error code indicating an error related to the operation of the pachi-slot machine 1, setting values, etc. on a digital display (not shown). In addition, the information display 13 includes an LED (not shown) that lights up when a replay pattern is displayed, an LED that lights up when the reels 3L, 3C, and 3R are operable and when medals can be inserted. (not shown) are provided.

On the left side of the front part of the pedestal part 10, a settlement button 12 is provided for switching credit/payout of the medals the player has won in the game by pressing the button. By switching the settlement button 12, the medals are paid out from the medal payout port 15 at the lower front, and the paid-out medals are accumulated in the medal receiving portion 16.例文帳に追加

On the right side of the checkout button 12, a start button is provided as a start operation means for rotating the reels 3L, 3C, and 3R by the player's tilting operation and starting the variable display of symbols in the display windows 4L, 4C, and 4R. A lever 6 is attached so as to be tiltable within a predetermined angle range.

Stop buttons 7L, 7C, and 7R as stop operation means for stopping the rotation of the three reels 3L, 3C, and 3R, respectively, are provided at substantially the center of the front surface of the pedestal 10 when pressed by the player. ing. In the embodiment, one game (one-unit game) basically starts when the start lever 6 is operated, and ends when all the reels 3L, 3C and 3R are stopped.

Speakers 9L and 9R are provided on the left and right sides of the front of the lower part of the front door 2 to produce sounds such as sound effects and voices. there is At the bottom of the front door 2, a medal receiving portion 16 for storing paid medals is provided.

A waist panel 25 with a design corresponding to the motif of the model is attached to the surface sandwiched between the stop buttons 7L, 7C, 7R and the medal receiving portion 16 in the front of the lower part of the front door 2. It is This waist panel 25 is illuminated by a waist panel illuminator (not shown) located behind it.

As shown in FIG. 4, inside the cabinet 60, a middle board 65 for reinforcing the cabinet 60 is provided substantially in the center. It is housed in and fixed to the reel cover 350 . A shield plate 355 is provided between the left reel 3L and the middle reel 3C and between the middle reel 3C and the right reel 3R to prevent light from passing through each other.

Each of the reels 3L, 3C and 3R has reel bands 300L, 300C and 300R on which a plurality of patterns as identification information composed of a plurality of types of patterns required for a game are arranged on the respective outer peripheral surfaces. The patterns on the respective reel bands 300L, 300C and 300R are visible from the outside of the pachi-slot machine 1 through display windows 4L, 4C and 4R (see FIG. 3). Further, each reel 3L, 3C, 3R rotates at a constant speed (for example, 80 rpm) to variably display the symbol rows.

In addition to the reels 3L, 3C, and 3R, a main control circuit 71 for controlling the pachi-slot machine 1 is housed in a main circuit board case, as shown in FIG. . Further, on the lower left side of the middle board 65, there is provided a power supply unit 20 having a power supply main switch and a power supply substrate for converting AC voltage into DC voltage. A medal payout device 40 that pays out medals when the number of paid-out winning prizes exceeds a predetermined number or at the time of payment is provided approximately in the center of the lower part of the middle board 65 . Further, on the lower right side of the middle board 65, a medal auxiliary storage box 45 for storing medals overflowing from the medal dispensing device 40 is provided.

<Detailed structure of the reel>
Next, referring to FIG. 5, the detailed configuration of the middle reel 3C will be described as an example of the reels 3L, 3C, and 3R. The left reel 3L and the right reel 3R have the same configuration except for the arrangement of a plurality of symbols arranged on the middle reel band 300C, the left reel band 300L and the right reel band 300R.

FIG. 5 is an exploded detailed view of the middle reel 3C. The middle reel 3C includes a middle reel band 300C, a rotatable reel drum 310 that supports the middle reel band 300C at its outer peripheral portion, a motor unit 320 that is arranged inside the reel drum 310 and drives the reel drum 310 to rotate, and a reel. A light-emitting part 330 that is arranged inside the drum 310 behind the reel band 300C and emits light, and a reel base 340 that holds them and is fixed to the upper surface of the middle board 65 (see FIG. 4) are provided.

(reel drum)
The reel drum 310 is rotatably supported by the reel base 340 and includes a pair of first circular frame 311 and second circular frame 312 each having a circular outer periphery. The first circular frame 311 has a side wall 315 formed in a substantially disk shape and is rotationally driven by a motor unit 320 . The side wall 315 is formed with an opening 315 a through which light is transmitted along the light emitting portion 330 . The second circular frame 312 includes a side wall 316 having a substantially eight-shaped diametrical cross section, and is joined to the central portion of the first circular frame 311 at its central portion. The side wall 316 is made of a translucent member that transmits light.

The ends of the first circular frame 311 and the second circular frame 312 are formed with reel band mounting portions 313 and 314 protruding toward the surfaces facing each other. The outer end, which is the outer end of the second circular frame 312, has chamfered corners. The reel band attachment portion 314 is formed on the central portion side opposite to the outer end portion, and is provided with a step so as to be separated from the outer end portion. Specifically, the reel band mounting portion 314 is formed closer to the rotating shaft side of the second circular frame 312 than the outer end portion.

The motor unit 320 includes a stepping motor 49C (see FIG. 8) that rotationally drives the reel drum 310, a motor drive circuit 39 (see FIG. 8) that controls the drive of the stepping motor 49C, and a motor drive circuit 39 (see FIG. 8) that rotates the reel drum 310 once. and a reel position detection circuit 50 (see FIG. 8) that detects a reel index indicating .

[Circuit Configuration of Pachislot]
The structure of the pachi-slot machine 1 has been described above. Next, with reference to FIGS. 8 to 10, the configuration of circuits provided in the pachi-slot machine 1 according to the present embodiment will be described. The pachi-slot machine 1 according to the present embodiment comprises a main control circuit 71, a sub-control circuit 72, an external centralized terminal board 73 electrically connected to them, and peripheral devices (actuators).

<Main control circuit>
FIG. 8 shows the configuration of the main control circuit 71 of the pachi-slot machine 1 according to this embodiment.

(Microcomputer)
The main control circuit 71 has the microcomputer 30 installed on the circuit board as a main component. The microcomputer 30 includes a CPU (hereinafter referred to as main CPU) 31 , a ROM (hereinafter referred to as main ROM) 32 and a RAM (hereinafter referred to as main RAM) 33 .

The main ROM 32 contains control programs executed by the main CPU 31 shown in FIG. Data and the like for sending instructions (commands) are stored. The main RAM 33 is provided with a storage area (see FIGS. 28 to 35) for storing various data such as an internal winning combination determined by executing the control program.

(random number generator, etc.)
A clock pulse generation circuit 34 , a frequency divider 35 , a random number generator 36 and a sampling circuit 37 are connected to the main CPU 31 . A clock pulse generation circuit 34 and a frequency divider 35 generate clock pulses.

The main CPU 31 executes the control program based on the generated clock pulses. The random number generator 36 generates random numbers within a predetermined range (eg, 0-65535). A sampling circuit 37 extracts at least one value from the generated random numbers according to the application.

(switch, etc.)
A switch or the like is connected to the input port of the microcomputer 30 . The main CPU 31 receives inputs from switches and the like, and controls operations of peripheral devices such as stepping motors 49L, 49C, and 49R.

The stop switch 7S constitutes stop operation detection means, and detects that each of the three stop buttons 7L, 7C, 7R has been pressed by the player (stop operation). Also, the start switch 6S detects that the start lever 6 has been operated by the player (start operation).

The medal sensor 42S detects that the medal received in the medal slot 22 has passed through the selector. Also, the bet switch 11S detects that the bet button 11 has been pressed by the player. Also, the settlement switch 12S detects that the settlement button 12 has been pressed by the player.

(peripheral devices and circuits)
Peripheral devices whose operations are controlled by the microcomputer 30 include stepping motors 49L, 49C, 49R and a medal payout device (hereinafter referred to as a hopper) 40. FIG.
Also, the output port of the microcomputer 30 is connected to a circuit for controlling the operation of each peripheral device.

The motor drive circuit 39 constitutes symbol variation means and controls the drive of stepping motors 49L, 49C and 49R provided corresponding to the respective reels 3L, 3C and 3R. The reel position detection circuit 50 detects a reel index indicating that the reels 3L, 3C and 3R have made one rotation according to each of the reels 3L, 3C and 3R by means of optical sensors having a light emitting portion and a light receiving portion.

The stepping motors 49L, 49C, and 49R have a momentum proportional to the number of pulse outputs, and have a configuration capable of stopping the rotating shaft at a specified angle. The driving forces of the stepping motors 49L, 49C, 49R are transmitted to the reels 3L, 3C, 3R through gears having a predetermined reduction ratio. Each time one pulse is output to the stepping motors 49L, 49C and 49R, the reels 3L, 3C and 3R rotate at a constant angle.

The main CPU 31 counts the number of times pulses are output to the stepping motors 49L, 49C, and 49R after detecting the reel index, thereby determining the rotation angles of the reels 3L, 3C, and 3R (mainly, the reels 3L, 3C, (how many symbols the 3R has rotated) is managed, and the position of each symbol arranged on the surface of the reels 3L, 3C, and 3R is managed.

In the pachi-slot machine 1, the time from when the start lever 6 is operated to when the reels 3L, 3C, and 3R normally start to rotate (hereinafter simply referred to as "reel operation time") is usually, unless a wait time, which will be described later, is taken into account. , is almost 0 seconds.

In the present embodiment, the main CPU 31 performs a long freeze process that takes a reel operating time longer than normal (for example, about 12 seconds), and a reel operating time that is longer than normal and shorter than that during long freeze processing (for example, about 2 seconds). and a short freeze process in which the reel operating time (for example, about 0.3 seconds) is longer than the normal time and shorter than the middle freeze process. Hereinafter, long freeze processing, middle freeze processing, and short freeze processing are collectively referred to as “freeze”.

A hopper drive circuit 41 controls the operation of the hopper 40 . In addition, the payout completion signal circuit 51 manages medal detection performed by the medal detection unit 40S provided in the hopper 40, and checks whether or not the number of medals paid out from the hopper 40 has reached the payout number. .

(Display, etc.)
Furthermore, the microcomputer 30 has stop button internal LEDs 107L, 107C, and 107R which are provided inside the stop buttons 7L, 7C, and 7R, respectively, to display the reception status of these buttons, and an information display 13, which displays information on the number of medals. is connected.

(External collective terminal board)
An output terminal 71a of the main control circuit 71 is connected to an external common terminal board 73 via a plurality of electric cables. This external centralized terminal board 73 receives signals from the main control circuit 71, such as the number of medals to be inserted/paid out, the number of games played, information on whether ART (BB, RB) is activated or not, etc., through an input terminal 73a. is output from the output terminal 73b to an external display for displaying the number of games played, the number of ART operations, etc., or to the host computer of the game arcade. The external display is installed above the pachi-slot machine 1, for example, and updates the display in conjunction with the progress of the number of games played and the operation of the ART, and notifies the operation of the ART by means of a lamp or the like.

Here, the medal insertion signal is a signal that enables recognition of medal insertion, and is output when the start lever 6 is operated. The medal pay-out signal is a signal that enables recognition of medal pay-out or replay, and is output at the time of medal pay-out (including credit accumulation) or at the time of re-game operation.

The external signal 1 is a signal that displays a BB tip, which will be described later, and makes it possible to recognize from the outside that ART is in progress. be.

The external signal 2 is a signal that displays an RB reply, which will be described later, and makes it possible to recognize from the outside that ART is in progress. be.

The external signals 3 and 4 are signals that make it possible to recognize an RWM error (that is, when the backup is not normal when the power is turned on), and are output during the initialization process when the power is turned on. The security signal is a signal that makes it possible to recognize when an error occurs (for example, when a medal is jammed, etc.), when the door is opened, when a setting is changed, etc., and is output when each event occurs.

<Sub control circuit>
FIG. 10 shows the configuration of the sub-control circuit 72 of the pachi-slot machine 1 according to this embodiment. The sub-control circuit 72 is electrically connected to the main control circuit 71, and performs processes such as determination and execution of effects based on commands transmitted from the main control circuit 71. FIG.

The sub-control circuit 72 basically includes a CPU (sub-CPU) 81, a ROM (sub-ROM) 82, a RAM (sub-RAM) 83, a DSP (digital signal processor) 84, an audio RAM 85, and a digital amplifier. 87 is included.

The sub CPU 81 controls output of video, sound, and light in accordance with the control program stored in the sub ROM 82 shown in FIG.

The sub-RAM 83 is provided with a storage area for registering determined effect contents and effect data, and a storage area for storing various data such as an internal winning combination transmitted from the main control circuit 71 . The sub-ROM 82 is basically composed of a program storage area and a data storage area.

A control program executed by the sub CPU 81 is stored in the program storage area. For example, the control program includes a main board communication task for controlling communication with the main control circuit 71 and determining and registering the contents of the performance (performance data) based on the content of the communication, a dot display 100, and a display on the reel. device 101, reel lighting device 102, reel effect display device 103, side effect display device 104, reel lower display device 105, bet button LED 108, LED output control task for controlling light output by light emitting unit 330, speaker 9L, 9R It includes a sound control task for controlling sound output.

The data storage area includes a storage area for storing various data tables, a storage area for storing effect data constituting each effect content, a storage area for storing animation data related to video creation, and first effect information related to BGM and sound effects. and a storage area for storing LED effect data as second effect information related to the light on/off pattern.

Also, the data storage area has LED effect data for controlling lighting and blinking of the dot indicator 100 . The sub-control circuit 72 controls the dot indicator 100 in accordance with the LED effect data, thereby controlling the lighting of LEDs at arbitrary locations among the LEDs of the dot indicator 100 . The LED effect data is arbitrarily designed by a designer in accordance with the design applied to the front panel 110. - 特許庁

The sub-control circuit 72 also includes, as peripheral devices whose operations are controlled, a dot display device 100, a reel upper display device 101, a reel lighting device 102, a reel effect display device 103, a side effect display device 104, and a reel lower display device. The device 105, the bet button LED 108, the light emitting section 330 and the speakers 9L and 9R are connected.

The sub CPU 81, the DSP 84, the audio RAM 85 and the digital amplifier 87 output sounds such as BGM from the speakers 9L and 9R according to the sound data specified by the content of the presentation.

The sub CPU 81 is configured to store specific sound data among the sound data stored in the sub ROM 82 in the audio RAM 85 at the start of the sound control task (see FIG. 92), which will be described later.

The DSP 84 is configured to reproduce the sound data transferred from the sub CPU 81 via the digital amplifier 87 with the speakers 9L and 9R. Thus, the DSP 84 that executes sound data constitutes first effect information execution means in this embodiment.

In addition, the sub CPU 81 controls the dot display device 100, the reel upper display device 101, the reel lighting device 102, the reel effect display device 103, the side effect display device 104, the reel lower display device 105, and the LED effect data specified by the effect content. Lighting and extinguishing of the light emitting unit 330 are performed.

In this way, the dot display device 100, the reel illuminator 102, the reel effect display device 103, the side effect display device 104, and the light emitting unit 330, which are lit and extinguished according to the LED effect data, and the output control of lighting and extinguishing of each member are executed. The sub CPU 81 that performs this constitutes second effect information execution means in the present embodiment. Further, the DSP 84 that executes sound data and the sub CPU 81 that executes output control of lighting and extinguishing of each member in accordance with the LED effect data constitute effect information executing means in the present embodiment. Also, the sub CPU 81 and DSP 84 are configured to be able to execute sound data and LED effect data by any of the peripheral devices connected to the sub control circuit 72 .

[Main game state transition]
As shown in FIG. 11, the pachi-slot machine 1 has a normal game state (RT0 game state), an RT1 game state, and an MB game state as main game states on the main control side controlled by the main control circuit 71 .

The RT0 gaming state is the initial state when the pachi-slot machine 1 is shipped. The main game state shifts to the RT0 game state when the MB game state ends. The RT0 gaming state is a gaming state in which a winning number is drawn by lottery based on the internal lottery table for normal gaming states (see FIG. 18), and is a low replay probability state in which the winning probability of a replay combination that is a replay combination is low.

The main game state shifts to the RT1 game state when the MB is won in the RT0 game state. The RT1 gaming state is a gaming state in which a winning number is drawn based on the internal lottery table for the RT1 gaming state (see FIG. 19), and is a high replay probability state in which the winning probability of the replay combination is higher than in the RT0 gaming state.

Here, the RT1 gaming state continues as long as an operating combination of MB, not RT managed by the number of games, wins. In that sense, the RT1 gaming state is infinite RT.

The main game state shifts to the MB game state when the MB operating combination wins in the RT1 game state. The MB gaming state is a gaming state in which all small wins are internally won, and ends when the number of payouts exceeds a predetermined number of payouts (30 in this embodiment).

Although the details will be described later, the pachi-slot machine 1 according to the present embodiment has a high probability of winning the MB in the RT0 game state, and it is difficult to win the operating combination of the MB in the RT1 game state. , the RT1 game state is taken as the main game state.

[ART game state transition]
As shown in FIG. 12, the pachi-slot machine 1 has a normal game state, an ART winning state, an ART start waiting state, and specific game states advantageous to the player as ART game states controlled by the main control circuit 71. There is an ART state.

Strictly speaking, the "ART gaming state" is the "AT gaming state". , "AT gaming state" in the present embodiment is referred to as "ART gaming state".

The main CPU 31 can selectively execute a lock that disables the game operation by the player for a predetermined period when a specific internal winning combination described later is won, when the one-unit game ends. For example, the game operation by the player includes an operation for starting the next unit game, such as a BET operation, insertion of medals, and lever operation during replay.

The ART game state shifts to the normal game state after the setting is changed or after the prescribed number of games is played in the ART state. The normal game state is a state in which the lock is restricted. Mainly, based on the release lottery table (see FIG. 52) and the unlocked game number lottery table (see FIGS. 46 to 51), the condition for releasing the lock is satisfied. It is a game state in which a lottery is drawn.

Here, the unlocking condition includes winning the lock release with a probability based on the unlocking lottery table (see FIG. 52) when any one of a plurality of special winnings to be described later is determined as an internal winning combination. , when a winning combination excluding a special winning combination among multiple winning combinations is determined as an internal winning combination (Others), the lock release is won with a probability based on the unlocking lottery table, and the unlocking game number lottery table (Fig. 46 to FIG. 51), the number of games has reached the number of games determined.

The ART game state shifts to the ART winning state (lock winning state) when the lock release condition is met in the normal game state, that is, when it is determined to lock. The ART winning state is a state in which the lock is released and the ART is won. Mainly, based on the internal lottery table for the RT1 gaming state (see FIG. 19), when a specific internal winning combination is internally won, the ART A game state in which it is determined by lottery that it is decided to lock, i.e., fulfillment of execution conditions for ART winning announcement indicating that an ART has been won, based on the lottery table (see FIG. 55). be.

The ART gaming state shifts to the ART start waiting state when the conditions for executing ART winning notification are established in the ART winning state. The ART start waiting state is a gaming state in which an ART winning announcement is made on the side of the sub-control circuit 72 and a method of winning a specific internal winning combination is reported (a winning mode is reported).

In the ART gaming state, when a specific internal winning combination is won in the ART start waiting state, a lock (hereinafter referred to as "starting lock") is executed, and the state shifts to the ART state. The ART state is mainly a game state in which the sub-control circuit 72 side notifies how to win an advantageous internal winning combination. In other words, the ART state is a game state in which advantageous stop operation information regarding awarding of medals is notified during a predetermined number of games.

On the main control circuit 71 side, when the number of games played in the ART state reaches a specified number (70 games or 20 games in this embodiment), a lock (hereinafter referred to as "end lock") is executed. , the ART game state shifts to the normal game state.

[Various data tables on the main control side]
13 to 26 show various data tables stored in the main ROM 32. FIG.

<Pattern arrangement table>
The symbol arrangement table shown in FIG. 13 represents the arrangement of symbols arranged on the surface of each of the left reel 3L, middle reel 3C and right reel 3R by data. The symbol arrangement table defines correspondence relationships between the 21 symbol positions "0" to "20" and the symbols corresponding to each of these symbol positions.

Symbol positions "0" to "20" indicate the positions of symbols arranged along the rotation direction on each of the left reel 3L, middle reel 3C and right reel 3R. The symbols corresponding to symbol positions "0" to "20" can be specified by referring to the symbol arrangement table using the value of the symbol counter.

The types of patterns are "Red 7", "BAR", "Cherry", "Watermelon A", "Watermelon B", "Watermelon C", "Bell", "Replay", "Blank A" and "Blank B". ” contains.

Here, "Watermelon A", "Watermelon B" and "Watermelon C" need only be identifiable as having different symbols inside the pachi-slot machine 1. The pattern should be recognizable by the person. Similarly, "Blank A" and "Blank B" need only be identifiable as different symbols inside the pachi-slot machine 1. and

The symbol arrangement table shown in FIG. 13 assigns symbols positioned in the middle of the display windows 4L, 4C, and 4R (symbols passing through the middle of the display windows) when the reel index is detected to symbol position "0". , and in order of movement in the rotational direction of the reels 3L, 3C, 3R.

In this way, by using the middle row of the display windows 4L, 4C, and 4R as a reference, the types of symbols positioned in the middle row of the display windows 4L, 4C, and 4R can be specified for each of the three reels 3L, 3C, and 3R. can be done.

<Design code table>
As shown in FIG. 14, each symbol placed on each reel 3L, 3C, 3R is identified by a symbol code table and distinguished by 1-byte (8-bit) data. The symbol code table shown in FIG. 14 represents codes for specifying symbols arranged on the surfaces of the three reels 3L, 3C, and 3R.

The symbols used in the pachi-slot machine 1 according to the present embodiment are, as described above, "red 7", "BAR", "cherry", "watermelon A", "watermelon B", "watermelon C", "bell", " Replay", "Blank A" and "Blank B".

In the symbol code table, "00000001" is assigned as data to the "red 7" symbol (symbol code 1). "00000010" is assigned as data to the "BAR" pattern (symbol code 2). "00000011" is assigned as data to the "cherry" pattern (symbol code 3).

Similarly, for each pattern of "Watermelon A", "Watermelon B", "Watermelon C", "Bell", "Replay", "Blank A" and "Blank B" (symbol codes 4 to 10), "00000100" to "00001010" are assigned as data.

<Design combination table>
The symbol combination table is divided into a bonus symbol combination table shown in FIG. 15, a replay symbol combination table shown in FIG. 16, and a small combination symbol combination table shown in FIG. Also in the combination table, the combination of symbols is associated with the winning operation flag and the number of payouts.

In the pachi-slot machine 1 of the present embodiment, the combination of symbols arranged along the activated winning line 8c is the object of determination for winning and operation. That is, it is determined whether or not the combination of symbols arranged along the activated pay line 8c (see FIG. 2) matches a predetermined predetermined combination of symbols.

This predetermined predetermined symbol combination is a symbol combination defined in the symbol combination table. When the combination of symbols arranged along the activated winning line 8c matches a predetermined combination of symbols, payout of medals, activation of replay, activation of bonus game, transition of game state, etc. are carried out. will be

(Pattern combination)
A symbol combination consists of a combination of symbols in the middle of each of the reels 3L, 3C, and 3R. A bonus combination, a replay combination, and a small combination are available as the combination (display combination) to be determined as the winning combination. Further, the small combination includes the cherry combination, the bell combination, and the watermelon combination, and the replay combination and the bonus combination are included in the activation combination.

As shown in FIG. 15, the bonus combination in this embodiment consists of "MB" as an operating combination of MB. "MB" is determined to win when "Blank A-BAR-Blank A" constituting MB1 transition symbols are lined up along the winning line 8c. The game state is shifted to the MB game state described above.

As shown in FIG. 16, the replay combination is a replay combination that allows the player to play the game with the same number of medals as the medals inserted to play the game without inserting new medals. The number of sheets is 0. The replay roles include "BB Lip 1", "BB Lip 2", "RB Lip", "Special Lip 1" to "Special Lip 11" and "Normal Lip".

"BB Rep 1" is a replay in which winning is determined when "Red 7-Red 7-Red 7" are aligned along the winning line 8c. "BB Rep 1" is a replay that shifts to the ART state with the stipulated number of games being 70 when a prize is determined in the above-described ART start waiting state.

"BB Rep 2" is a replay that is determined to win when "Blank A-Red 7-BAR" is lined up along the winning line 8c. Like "BB reply 1", "BB reply 2" is a replay that shifts to the ART state with the stipulated number of games being 70 when winning is determined in the ART start waiting state.

"RB Rep" is a replay in which winning is determined when "Red 7-Red 7-BAR" are aligned along the winning line 8c. In addition, unlike ``BB lip 1'' and ``BB lip 2'', ``RB lip'' is a replay that shifts to the ART state with the prescribed number of games of 20 games when a prize is determined in the above-mentioned ART start waiting state. be.

"Special reply 1" is determined to win when "Bell-Red 7-Red 7" are lined up along the winning line 8c, and on the main control side, it is a normal replay like the "normal reply" described later. . "Special reply 2" to "special reply 11" are different from "special reply 1" only in the patterns arranged along the winning line 8c, and are normal replays like "special reply 1".

A "normal replay" is a normal replay that is determined to win a prize when "replay-replay-replay" is arranged along the winning line 8c.

As shown in FIG. 17, the cherry combination includes "special cherry", "cherry 1" to "cherry 11", and "middle cherry 1" to "middle cherry 5", and medals are thrown for each cherry combination. The payout number is one when the number is three and the prize is won.

Here, the "special cherry" is determined to win when "BAR-BAR-ANY (any symbol)" is lined up along the winning line 8c. "Cherry 1" to "Cherry 11" and "Middle Cherry 1" to "Middle Cherry 5" are determined to win when the corresponding symbol combinations in FIG. 17 are aligned along the winning line 8c.

"Special Small Win 1" is determined to win when "Blank A-Watermelon A-Red 7" are aligned along the pay line 8c. "Special small winning combination 2" to "special small winning combination 4" are determined to win when corresponding symbol combinations in FIG. 17 line up along the winning line 8c. In each of these special small wins, the number of payouts is one when the number of inserted medals is three and the player wins.

"Watermelon 1" is determined to win a prize when "Bell-Watermelon A-Red 7" are lined up along the prize line 8c. "Watermelon 2" to "Watermelon 4" are determined to win when corresponding symbol combinations in FIG. 17 are aligned along the winning line 8c. For these watermelons, the payout number is four when the number of inserted medals is three and the player wins.

The bell role is the "middle bell" where the number of payouts is 9 when the number of medals inserted is 3 and the number of payouts when the number of medals is 3 is 3. It includes "lower bell 1" to "lower bell 3" and "special bell 1" to "special bell 40" in which the number of payouts is one when the number of inserted medals is three and the player wins.

"Middle bell" is determined to win when "Bell-Bell-Bell" is lined up along the prize line 8c. "Lower bell 1" to "lower bell 3" are performed when "Watermelon A-Bell-Replay", "Watermelon B-Bell-Replay", and "Watermelon C-Bell-Replay" are lined up along the winning line 8c. Each will be awarded a prize.

"Special bell 1" is determined to win a prize when "Replay-Watermelon A-BAR" is lined up along the prize line 8c. "Special bell 2" to "special bell 40" are determined to win when corresponding combinations of symbols are aligned in FIG. 17 along the winning line 8c.

(winning operation flag)
Winning operation flags in FIGS. 15 to 17 are data assigned corresponding to unique symbol combinations to indicate display combinations, and include 1-byte (8-bit) data and a storage area type. The storage area type is data for distinguishing 1-byte data. The 1-byte data contains data regarding a combination of multiple symbols. Each symbol combination (display combination) is distinguished by a storage area type and 1-byte data.

In this embodiment, as shown in FIGS. 15 to 17, there are more than 8 combinations of symbols. Combinations cannot be specified or identified.

Therefore, in this embodiment, storage area types 1 to 12 are used to distinguish 1-byte data. By doing so, even if the value of the 1-byte data is the same, by designating any one of the storage area types 1 to 12, more than 8 kinds of combinations of patterns can be combined with different patterns. can be treated as

For example, storage area type 1 is assigned to "MB". Storage area type 2 is assigned to "BB descriptor 1", "BB descriptor 2", "RB descriptor", and "special descriptor 1" to "special descriptor 5".

Storage area type 3 is assigned to "special reply 6" to "special reply 11" and "normal reply". Storage area type 4 is assigned to "special cherry" and "cherry 1" to "cherry 7".

Storage area type 5 is assigned to "cherry 8" to "cherry 11" and "middle cherry 1" to "middle cherry 4". Storage area type 6 is assigned to "middle cherry 5", "special small winning combination 1" to "special small winning combination 4", and "watermelon 1" to "watermelon 3".

Storage area type 7 is assigned to "watermelon 4", "middle bell", "lower bell 1" to "lower bell 3", and "special bell 1" to "special bell 3". Thus, hereinafter, "special bell 4" to "special bell 40" and "encode" are assigned to storage area types 8 to 12, respectively.

As for the 1-byte data, the bit corresponding to each display combination is set to "1" and the remaining bits are set to "0" for the assigned storage area type.

For example, by setting the value of the storage area type to "2" and the value of the 1-byte data to "00000001", the display combination "BB descriptor 1" can be specified, and the value of the storage area type can be set to " 7” and the value of the 1-byte data is “00000010”, it is possible to specify the display combination “middle bell”.

(Number of payouts)
The number of payouts in FIGS. 15 to 17 is data indicating the number of medals to be paid out to the player corresponding to each combination of symbols. When the combination of symbols arranged along the winning line 8c matches the "combination of symbols" in the symbol combination table, the payout of medals by driving the hopper device 40 and the number of credits are counted based on the corresponding number of payouts. A credit counter is incremented.

The payout number for the replay combination is 0. The payout number for the cherry combination and the special small combination is 1 when the number of inserted coins is 3, and the payout number for the watermelon combination is 4 when the number of inserted coins is 3. In addition, among the bell roles, the number of payouts for "middle bell" is 9 when the number of inserts is 3, and the number of payouts for "lower bell 1" to "lower bell 3" is 3 when the number of inserts is 3. , and the payout number of "special bell 1" to "special bell 40" is 1 when the number of inserted bells is 3. When the number of inserted coins is 2 (MB gaming state), the number of payouts for the cherry combination, watermelon combination, special small combination, watermelon combination, and bell combination is 2.

<Internal lottery table for general gaming state>
In the internal lottery table for normal gaming state shown in FIG. 18, the lottery value and data pointer for each set value are associated with the winning number when the main game state is the normal gaming state (RT0 gaming state). .

In this embodiment, random numbers for lottery extracted from a predetermined numerical range “0 to 65535” are sequentially subtracted by lottery values corresponding to each winning number, and whether the result of the subtraction is negative or not. An internal lottery is performed by determining whether or not (whether or not a so-called "calculation" has occurred).

Therefore, the larger the numerical value defined as the lottery value, the higher the probability that the data to which it is assigned (that is, the data pointer) will be determined. That is, the winning probability of each winning number can be represented by "the lottery value corresponding to each winning number/the number of all possible random numbers to be extracted (65536)".

Here, when the number of times of determination processing as to whether or not the result of subtraction is negative exceeds the number of winning numbers, the result of the internal lottery processing is “losing”. is set so that the number of times of determining whether or not the result of is negative does not exceed the number of winning numbers.

The data pointer is data acquired as a result of a lottery performed by referring to the internal lottery table for general gaming state, and is data for designating an internal winning combination defined by an internal winning combination determination table to be described later. .

That is, the data pointer is data used for determining the storage area type and 1-byte data in the winning combination determination table for minor combination replay shown in FIG. 20 and the internal winning combination determination table for bonus shown in FIG. As for the data pointers, a small combination/replay data pointer and a bonus data pointer are individually defined corresponding to each of a plurality of winning numbers.

As shown in FIG. 18, in the internal lottery table for the normal gaming state, the lottery value "0" is associated with the lottery numbers "1" and "2" so that the lottery numbers "1" and "2" are not won, and the lottery numbers "3" and "31" are associated with each other. ” to “35” are associated with common lottery values for the set values “1” to “6”, and the winning numbers “4” to “30” and “36” have smaller numbers as the set values become higher. The lottery values are associated so that

In the small combination/replay data pointer, the value corresponding to the winning number is associated with the winning numbers "1" to "35", and "0" is associated with the winning number "36". It is On the other hand, as for the bonus data pointer, "0" is associated with the winning numbers "1" to "35", and "1" is associated with the winning number "36". .

<Internal lottery table for RT1 gaming state>
In the RT1 gaming state internal lottery table shown in FIG. 19, a lottery value and a data pointer for each set value are associated with a winning number when the main gaming state is the RT1 gaming state.

Since the RT1 gaming state internal lottery table is configured in the same manner as the normal gaming state internal lottery table shown in FIG. Description of the same parts as those of the internal lottery table for general game state will be omitted, including illustration.

In the internal lottery table for the RT1 gaming state, when the main gaming state is the RT1 gaming state, the MB is won and the non-operating MB is carried over, so the winning number "36" corresponding to the MB winning number is do not have.

In the internal lottery table for the RT1 gaming state, lottery values are associated with the lottery numbers "1" and "2" so that the higher the set value, the smaller the lottery value, and the lottery is made so that the lottery number "3" is not won. "0" is associated as a value.

<Small win/replay internal winning combination determination table>
In the internal winning combination determination table for minor winning combination replay shown in FIG. It is associated with an internal winning combination (replay combination) that allows the display of a combination of symbols related to the operation. The content of the internal winning combination is determined according to the small combination/replay data pointers "1" to "35".

The small win/replay data pointers are "1" to "3" corresponding to the replay win, "4" to "30" corresponding to the bell win, "31" corresponding to the watermelon win, and "" corresponding to the cherry win. 32” to “34” and “35” corresponding to a special small winning combination correspond to 12 pieces of 1-byte data.

When the data pointer for small win/replay is "1", "BB reply 1", "BB reply 2", "RB reply", "special reply 1" to "special reply 9" and "normal reply" is duplicated and internally won.

For the sake of convenience, such a combination in which the internal winning combination overlaps (duplicate combination) is also referred to as "bonus reply 1". Also, "BB Lip 1", "BB Lip 2" and "RB Lip" correspond to the specific internal winning combinations described above.

When the data pointer for small win/replay is "2", "BB reply 1", "BB reply 2", "RB reply", "special reply 1" to "special reply 10" and "normal reply" is duplicated and internally won. For the sake of convenience, this overlapping role is also referred to as "bonus reply 2". If the small win/replay data pointer is "3", it means that the "normal replay" has been internally won.

When the small win/replay data pointer is "4", it means that the "lower bells 1 to 3" and the "special bells 1 to 3" are duplicated and internally won. When this double combination is won, the order of pressing the stop button 7C or 7R as the first stop operation of the stop buttons 7L, 7C, and 7R is the correct answer, and the lower bells 1 to 3 can be won. . For the sake of convenience, this overlapping role is also referred to as "middle right 1st bell 1".

Similarly, when the small win/replay data pointer is "5", "lower bells 1 to 3" and "special bells 4 to 6, 10 to 12" are duplicated and internally won. Thus, when the small combination/replay data pointer is "6", "lower bells 1 to 3" and "special bells 7 to 9" are duplicated and internally won.

When the data pointer for minor win/replay is "7", it means that "middle bell" and "special bell 1, 7, 13, 17, 18, 20 to 22" are duplicated and internally won. Become.

When this double combination is won, the pressing order is correct when pressing the stop button 7C as the first stop operation, the stop button 7L as the second stop operation, and the stop button 7R as the third stop operation, and the middle bell wins. It becomes possible. For the sake of convenience, this overlapping role is also referred to as "middle left and right bell 1".

Similarly, when the small win/replay data pointer is "8", "middle bell" and "special bell 2, 8, 14 to 16, 19, 23, 24" are duplicated and internally won. When the small win/replay data pointer is "9", the "middle bell" and "special bells 3, 9, 13, 17, 18, 20 to 22" overlap and are internally won. It means that

Further, when the small win/replay data pointer is "10", "middle bell" and "special bell 4, 10, 14 to 16, 19, 23, 24" are duplicated and internally won. Therefore, when the small win/replay data pointer is "11", the "middle bell" and "special bell 5, 11, 13, 17, 18, 20 to 22" are duplicated and internally won. It means that

Further, when the small win/replay data pointer is "12", "middle bell" and "special bell 6, 12, 14 to 16, 19, 23, 24" are duplicated and internally won. Therefore, when the small win/replay data pointer is "13", "middle bell" and "special bell 1, 7, 13, 14, 16, 18, 19, 21, 23, 24" It means that the internal winning is duplicated.

When this double combination is won, the pressing order is correct when pressing the stop button 7C as the first stop operation, the stop button 7R as the second stop operation, and the stop button 7L as the third stop operation, and the middle bell wins. It becomes possible. For the sake of convenience, this overlapping combination is also referred to as "middle right left bell 1".

Similarly, when the small win/replay data pointer is "14", the "middle bell" and the "special bell 2, 8, 13, 15, 17, 18, 20 to 23" overlap and are internally won. When the data pointer for minor win/replay is "15", "middle bell" and "special bell 3, 9, 14 to 17, 19, 20, 22, 24" overlap. It means that the internal lottery is won.

Further, when the small win/replay data pointer is "16", "middle bell" and "special bell 4, 10, 13, 14, 16, 18, 19, 21, 23, 24" overlap. When the small win/replay data pointer is "17", "middle bell" and "special bell 5, 11, 13, 15, 17, 18, 20-23" It means that the internal winning is duplicated.

Furthermore, when the small win/replay data pointer is "18", the "middle bell" and "special bells 6, 12, 14 to 17, 19, 20, 22, 24" are duplicated and internally won. When the small win/replay data pointer is "19", "middle bell" and "special bell 1, 7, 25, 27, 30, 32, 34, 36, 37, 39" It means that the internal winning is duplicated.

When this double combination is won, the pressing order becomes correct when pressing the stop button 7R as the first stop operation, the stop button 7L as the second stop operation, and the stop button 7C as the third stop operation, and the middle bell wins. It becomes possible. For the sake of convenience, this overlapping combination is also referred to as "right and left middle bell 1".

Similarly, when the small win/replay data pointer is "20", "middle bell" and "special bell 2, 8, 26, 28, 29, 31, 33, 35, 38, 40" overlap. When the small win/replay data pointer is "21", "middle bell" and "special bell 3, 9, 25, 27, 30, 32, 34, 36 , 37, 39” are duplicated and internally won.

Further, when the small win/replay data pointer is "22", "middle bell" and "special bell 4, 10, 26, 28, 29, 31, 33, 35, 38, 40" overlap. When the small win/replay data pointer is "23", "middle bell" and "special bell 5, 11, 25, 27, 30, 32, 34, 36, 37, 39” are duplicated and internally won.

Furthermore, when the small win/replay data pointer is "24", "middle bell" and "special bell 6, 12, 26, 28, 29, 31, 33, 35, 38, 40" overlap. When the small win/replay data pointer is "25", "middle bell" and "special bell 1, 7, 26, 28, 29, 31, 33, 35, 38, 40" are duplicated and internally won.

When this double combination is won, the pressing order is correct when pressing the stop button 7R as the first stop operation, the stop button 7C as the second stop operation, and the stop button 7L as the third stop operation, and the middle bell wins. It becomes possible. For the sake of convenience, this overlapping combination is also referred to as "right middle left bell 1".

Similarly, when the small win/replay data pointer is "26", "middle bell" and "special bell 2, 8, 25, 27, 30, 32, 34, 36, 37, 39" overlap. When the small win/replay data pointer is "27", "middle bell" and "special bell 3, 9, 26, 28, 29, 31, 33, 35 , 38, 40” are duplicated and internally won.

Further, when the data pointer for minor win/replay is "28", "middle bell" and "special bell 4, 10, 25, 27, 30, 32, 34, 36, 37, 39" overlap. When the small win/replay data pointer is "29", "middle bell" and "special bell 5, 11, 26, 28, 29, 31, 33, 35, 38, 40" are duplicated and internally won, and when the small win/replay data pointer is "30", "middle bell" and "special bell 6, 12, 25, 27, 30, 32, 34, 36, 37, 39" are duplicated and internally won.

If the small win/replay data pointer is "31", it means that "Watermelon 1 to 4" has been internally won. For convenience, this overlapping role is also called "watermelon".

When the data pointer for small win/replay is "32", "special cherry" and "cherry 1 to 9" are duplicated and internally won. For convenience, this overlapping role is also called "corner cherry".

When the small win/replay data pointer is "33", the "special cherry" and the "cherries 1 to 11" are duplicated and internally won. For the sake of convenience, this overlapping role is also referred to as "fixed cherry".

When the small win/replay data pointer is "34", "special cherries", "cherries 1 to 11" and "middle cherries 1 to 5" are duplicated and internally won. For convenience, this overlapping role is also called "middle cherry".

When the small winning combination/replay data pointer is "35", it means that the "special small winning combination 1 to 4" has been internally won. For the sake of convenience, this overlapping combination is also referred to as a "fixed small combination".

<Bonus internal winning combination determination table>
In the bonus internal winning combination determination table shown in FIG. 21, the bonus data pointer is associated with an internal winning combination that allows the display of the symbol combination associated with the activation of the bonus.

In the bonus data pointer, "0" corresponding to a loss and "1" corresponding to "MB" correspond to 12 pieces of 1-byte data. If the bonus data pointer is "1", it means that "MB" has been internally won.

<Reel stop initial setting table>
In the reel stop initial setting table shown in FIG. 22, pull-in priority table selection data or a pull-in priority table number and a stop table selection data group are associated with reel stop numbers. These various data indicate various table numbers to be selected in the stop control of the reels 3L, 3C and 3R according to the progress of the 1-unit game.

The attraction priority table selection data is a number for selecting an attraction priority table selection table shown in FIG. 23 to be described later. The "attraction priority table number" is a number for selecting an attraction priority table shown in FIG. 24, which will be described later.

Although the details are omitted, the "stop table selection data group" is a number for selecting a stop table or the like that stores the reel pressing position and the number of sliding symbols in association with each other. These numbers are data used for determining the "sliding piece number determination data", that is, determining the positions to stop the three reels 3L, 3C, and 3R according to the progress of the 1-unit game. .

In the reel stop initial setting table, the pull-in priority table selection data is associated with the reel stop number corresponding to the data pointer for which different stop control is performed depending on the order of the stop operation, regardless of the order of the stop operation. A pull-in priority table number is associated with the reel stop number corresponding to the data pointer for which the stop control does not change.

<Attraction Priority Table Selection Table>
In the attraction priority table selection table shown in FIG. 23, attraction priority table numbers are associated with stop operation types indicating the order of stop operations for each attraction priority table selection data.

For example, in the attraction priority table selection data "01", when the first stop operation is "left", the attraction priority table number "00" is associated, and the first stop operation is "middle". In this case, the attraction priority table number "09" is associated.

In addition, in the attraction priority table selection data "01", when the first stop operation is "left" and the second stop operation is "middle" at the time of the second stop operation ("left → middle" in the figure), When the attraction priority table number "00" is associated and the first stop operation is "right" and the second stop operation is "left" at the time of the second stop operation ("right → left" in the figure), The attraction priority table number "03" is associated.

<Attraction Priority Table>
The attraction priority order table shown in FIG. 24 indicates which symbol is to be preferentially attracted when there are a plurality of symbols (symbols corresponding to the combination determined as the internal winning combination) that may be displayed within the attraction range. ing. In addition, in FIG. 24, the data of the winning actuation flag is omitted for the sake of simplicity.

The attraction-in priority table shows attraction-in data indicating the attraction-in priority of the symbol combination associated with the winning operation flag (display combination). The “attraction priority data” is information provided for the main CPU 31 to identify the attraction priority.

Here, "pull-in" means the rotation of the reels 3L, 3C and 3R so as to display, along the winning line 8c, the symbols constituting the combination of symbols relating to the internal winning combination within the range of the maximum number of sliding symbols. means to stop

For example, in the attraction priority table number "00", if it is determined that there is a possibility of winning the prize operation flag "normal reply" and the prize operation flag "special reply", " Since "Normal Rip" has a higher priority, the reels 3L, 3C and 3R are controlled to stop rotating so that "Normal Rip" is preferentially pulled.

<Priority order table>
The priority order table shown in FIG. 25 defines the priority order of the number of sliding symbols when the main game state is other than the MB game state. The priority order table specifies the order (hereinafter referred to as the priority order) in which applicable numerical values are preferentially applied from the numerical range (that is, 0 to 4) of the number of sliding symbols determined in advance as the number of sliding symbols. stipulate.

<Priority order table for MB gaming state>
The MB game state priority order table shown in FIG. 26 defines the priority order of the number of sliding symbols when the main game state is the MB game state. The priority order table for MB gaming state defines the priority order of applicable numerical values from the numerical range (that is, 0 or 1) of the number of sliding symbols determined in advance as the number of sliding symbols.

In these priority order table and priority order table for MB game state, each numerical value is searched in order of priority order from high (1) to low (5). applied preferentially. The priority order table is provided on the assumption that there are multiple numbers of sliding symbols with the same attraction priority, and the number of sliding symbols with a higher priority order is applied.

The priority order table and MB gaming state priority order table in the present embodiment define the priority order based on the sliding symbol number determination data. In other words, the priority order is defined so that the numerical value corresponding to the number of sliding symbols determination data is the highest. As a result, the data for determining the number of sliding symbols is determined with priority over the number of other sliding symbols, so the display of the symbols intended at the time of development of the stop table is given priority.

<Relationship Diagram Between Winning Combinations and Winning Combinations by Stop Operation Order>
In this embodiment, by using the various tables described above, the relationship between the internal winning combination and the winning combination according to the stop operation order of the stop buttons 7L, 7C and 7R is as shown in FIG.

For example, when the internal winning combination of winning number 1 is extracted, the first stop operation is "left", that is, when the stop button 7L is operated for the first stop, "normal response" is won.

Further, when the internal winning combination of winning number 1 is extracted and the first stop operation is "middle", that is, when the stop button 7C is operated for the first stop, the correct pressed position is "BB description 1" or "BB description". 2” wins the prize, and “Normal reply” wins when the pressed position is incorrect.

Here, the correct pressed position is the range of the maximum number of sliding pieces (4 pieces) from the symbol position of the effective line (the center line 8c in this embodiment) when the player presses the stop buttons 7L, 7C, 7R. It means that there is a symbol constituting a symbol combination related to the target internal winning combination, and that symbol can be stopped on the active line.

In the present embodiment, the priority of "BB reply 1" or "BB reply 2" when the pressed position is correct differs for each stop operation order of "middle left/right" and "middle right/left". In the case of the stop operation order of "left and right", the priority of "BB reply 1" is higher than that of "BB reply 2".

Further, when the internal winning combination of the winning number 1 is extracted, the first stop operation is "right", that is, when the stop button 7R is operated for the first stop, the pressed position is correct and "RB Lip" is won and pressed. "Normal reply" wins for incorrect position.

Further, when the internal winning combination of winning number 2 is extracted, the mode is opposite to the above-described case of winning number 1, and when the first stop operation is "right", the correct pressing position is "BB Lip 1". Or "BB reply 2" will win, and "Normal reply" will win if the pressed position is incorrect. Also, when the first stop operation is "medium", "RB reply" is awarded for the correct pressing position, and "normal reply" is awarded for the incorrect pressing position.

As described above, in the present embodiment, the winning modes in which the "bonus descriptions 1 and 2" corresponding to the winning numbers 1 and 2 are won are "BB description 1" or "BB description 2" and "RB There is a lip. Here, "RB reply" is the first winning mode, and "BB reply 1" and "BB reply 2" are the second winning mode.

Further, in the present embodiment, as shown in FIG. 27, "Bonus reply 1" and "Bonus reply 2" are determined according to the stop operation order. Winning patterns for winning are different.

In other words, the winning pattern (first winning pattern) according to the stop operation order of "bonus reply 1" is based on the assumption that the pressing position is correct, and when the first stop operation is "middle", "BB reply 1" or "BB reply 2" wins a prize, and when the first stop operation is "right", a "RB reply" wins.

Here, when the first stop operation is "medium", it corresponds to the first stop operation order for winning "BB description 1" or "BB description 2". Also, when the first stop operation is "right", it corresponds to the second stop operation order for winning "RB Lip".

On the other hand, the winning pattern (second winning pattern) based on the stop operation order of "bonus reply 2" is based on the premise that the pressing position is correct, and when the first stop operation is "medium", "RB reply" wins, If the first stop operation is "right", "BB reply 1" or "BB reply 2" will be won.

Here, when the first stop operation is "Right", it corresponds to the first stop operation order for winning "BB Lip 1" or "BB Lip 2". Also, when the first stop operation is "middle", it corresponds to the second stop operation order for winning "RB reply".

In addition, "lower bells 1 to 3" and "middle bells" can win prizes when the first stop operation is in a stop operation order other than "left". In other words, these "lower bells 1 to 3" and "middle bells" are normally not awarded when the first stop operation is "left" and the main game state is the normal game state.

In addition, among the internal winning combinations related to winning numbers 4 to 30, except when "lower bell 1 to 3" and "middle bell" are won, "special bell 1 to 40” will win a prize.

Further, the internal winning combinations associated with the winning numbers 31 to 36 are won by the corresponding internal winning combinations (eg, watermelon 1 to 4, special cherry, etc.) by pressing the correct position. When the internal winning combination of winning number 34 is extracted and the first stop operation is "left", "middle cherries 1-5" are preferred over "special cherries" and "cherries 1-11". has a higher priority.

[Various storage areas on the main control side]
28 to 35 are diagrams showing examples of various storage areas stored in the main RAM 33. FIG.

<Internal Winning Combination Storage Area>
The internal winning combination storage area shown in FIG. 28 is composed of 12 storage areas of internal winning combination storage areas 1-12. The size of each storage area of these internal winning combination storage areas 1 to 12 is 1 byte.

Therefore, the total size of the internal winning combination storing areas 1 to 12 is 12 bytes. The internal winning combination storage areas 1 to 12 store data determined based on the internal winning combination data (storage area type) defined by the internal winning combination determination table for minor combination replay shown in FIG.

In the illustrated internal winning combination storing area, for example, bit 0 of the internal winning combination storing area 1 corresponds to "MB", and bits 1 to 7 are unused.

Similarly, bits 0 to 4 of the internal winning combination storage area 12 correspond to "special bell 36", "special bell 37", "special bell 38", "special bell 39" and "special bell 40", respectively. , bits 5 to 7 are unused.

<Display unit storage area>
The display combination storing area shown in FIG. 29 is composed of 18 storage areas of display combination storing areas 1 to 18 . The size of each storage area of these display combination storage areas 1 to 18 is 1 byte.

Therefore, the total size of the display combination storing areas 1 to 18 is 18 bytes. The display combination storage areas 1 to 18 store data determined based on display combination data (storage area type) defined by each symbol combination table (bonus, replay, small combination) shown in FIGS. 15 to 17. . The value in the display combination storage area is used by the main CPU 31 to identify the display combination after all of the reels 3L, 3C and 3R are stopped.

In the illustrated display combination storing area, for example, bit 0 of the display combination storing area 1 corresponds to "MB", and bits 1 to 7 are unused.

Similarly, bits 0 to 4 of the display combination storing area 18 correspond to "special bell 36", "special bell 37", "special bell 38", "special bell 39", and "special bell 40" respectively. Bits 5 to 7 are unused.

<Design code storage area>
The symbol code storage area shown in FIG. 30 is configured similarly to the display combination storage area shown in FIG. Therefore, detailed description is omitted.

The pattern code storage area stores data indicating winnable combinations on the rotating reels. For example, when all of the reels 3L, 3C, and 3R are spinning, all winning combinations are possible, so all corresponding bits in the symbol code storage area are set to "1". After that, when the left reel 3L stops (reels 3C and 3R rotate), the bit corresponding to the winning combination that cannot be won due to the stop of the left reel 3L is updated to "0".

Referring to FIG. 17, for example, when the "blank A" symbol stops on the left reel 3L, the bits corresponding to the special bells 33 to 36 with the "watermelon A" symbol on the left reel 3L are While the symbol on the left reel 3L is updated to "0", the bits corresponding to the cherry 6 and the special small wins 1 to 4 whose symbol is the "blank A" symbol are maintained as "1".

<Operation stop button storage area>
The operation stop button storage area shown in FIG. 31 is 1 byte in size. Bits 4 to 6 are storage areas indicating the stop buttons 7L, 7C, 7R capable of detecting the stop operation by the player, that is, the valid stop buttons 7L, 7C, 7R.

Bits 0 to 2 are storage areas indicating the stop buttons 7L, 7C, 7R for which the stop operation corresponding to the valid stop buttons 7L, 7C, 7R was detected immediately before. In this embodiment, bit 3 and bit 7 are not used, and "0" is stored.

Bit 0 corresponds to the left stop button 7L. When the left stop button 7L is operated by the player, "1" is stored in bit 0. Bit 1 corresponds to the middle stop button 7C. When the middle stop button 7C is operated by the player, "1" is stored in bit 1. Bit 2 corresponds to the right stop button 7R. When the right stop button 7R is operated by the player, "1" is stored in bit 2.

Bit 4 corresponds to the left stop button 7L. A "1" is stored in bit 4 when the left stop button 7L is enabled. Bit 5 corresponds to the middle stop button 7C. A "1" is stored in bit 5 when the middle stop button 7C is enabled. Bit 6 corresponds to the right stop button 7R.

A "1" is stored in bit 6 when the right stop button 7R is enabled. In this embodiment, that the stop button is enabled means that the stop operation can be detected. The stop buttons 7L, 7C, 7R corresponding to the reels rotating at a constant speed and whose stop operation can be detected are called effective stop buttons.

<Press order storage area>
The pressing order storage area shown in FIG. 32 is an area for storing information indicating the pressing order of the three stop buttons 7L, 7C, and 7R. This pressing order storage area has a size of 1 byte, bits 0 to 5 are used, bits 6 and 7 are unused, and "0" is stored.

Bit 0 corresponds to the pressing order of "left→middle→right", and "1" is stored (turned on) in bit 0 when the pressing order is "left→middle→right". Similarly, if the pressing order is "left→right→middle", "1" is stored (turned on) in bit 1, and if the pressing order is "middle→left→right", "1" is stored in bit 2. is stored (turned on), "1" is stored (turned on) in bit 3 in the case of "middle → right → left", and "1" is stored in bit 4 in the case of "right → left → middle". In the case of "right→middle→left", "1" is stored in bit 5 (turned on).

<Storage area for carryover combination>
The carryover combination storage area shown in FIG. 33 has a size of 1 byte, bit 0 corresponds to "MB", and bits 1 to 7 are unused. When the internal winning combination "MB" is determined as a result of the internal lottery processing, "1" is stored in bit 0 of the carryover combination storing area.

By storing "1" in bit 0 of the carryover combination storing area, it can be determined that "MB" has been won. The state in which "1" is stored in the bit 0 of the carryover combination storing area is maintained until the symbol combination corresponding to "MB" is displayed on the winning line 8c.

That is, when "MB" is won, bit 0 of the carryover combination storing area is set to "1" in at least one unit game until the combination of these bonus symbols is displayed as a display combination on the winning line 8c. Stored state is retained. Maintaining the state in which "1" is stored in bit 0 from the unit game in which the bonus is won to the unit game in which a prize is won is called "carry over". The "MB" stored in the carryover combination storing area is referred to as a "carryover combination".

When the player performs a stop operation and the reels 3L, 3C and 3R stop rotating, the internal winning combination storing area is initialized, but the carryover combination storing area is not initialized.
By doing so, the state of "carried over" can be maintained.

<Game state flag storage area>
The game state flag storage area shown in FIG. 34 indicates whether the main game state is the bonus game state or the RT1 game state, and whether the ART game state is the ART winning state, the ART start waiting state, or the ART state. The size of the flag is 1 byte.

Bits 0 and 1 of the game state flag storage area relate to the bonus game state, and bit 2 relates to the main game state. Bits 4 to 6 of the game state flag storage area relate to the ART game state. In this embodiment, bit 3 and bit 7 of the gaming state flag storage area are unused.

In the bonus game state, bit 0 of the game state flag storage area is set to "1" (on) in the MB game state, and bit 1 of the game state flag storage area is set to "1" (on) in the CB game state. It is said that

When the main game state is the RT1 game state, bit 2 of the game state flag storage area is set to "1" (ON).

Also, when the ART game state is the ART winning state, bit 4 of the game state flag storage area is set to "1" (ON), and when the ART game state is waiting for the start of ART, bit 5 of the game state flag storage area is set to " 1" (on), and when the state is ART, bit 6 of the game state flag storage area is set to "1" (on).

<Attraction priority data storage area>
The attraction priority data storage area shown in FIG. 35 includes an attraction priority data storage area for the left reel, an attraction priority data storage area for the middle reel, and an attraction priority data storage area for the right reel.

Since the contents of the attraction priority data storage area for the middle reel and the attraction priority data storage area for the right reel are the same as those of the attraction priority data storage area for the left reel, the attraction priority data storage area for the left reel will be described below. A data storage area will be described.

The left reel attraction priority data storage area can store attraction priority data for each symbol position data (see FIG. 13). For example, for symbol position data 0, a combination (any one of 0FEH to 000H) defined in priorities 1 to 5 in FIG. 24 is defined. One of the pull-in priority data is stored in the reels 3C and 3R according to the stop position. As a result, the left reel 3L is controlled to stop or not to stop the symbol corresponding to the winning combination on the pay line 8c.

Similarly, for the symbol position data 1 to 20, the combination to be defined in the priority order is defined respectively. Accordingly, any attraction priority data is stored.

<Overview of each mode>
The overview of each mode shown in FIG. 36 indicates an overview of each of the plurality of stay modes in the ART gaming state.

In the present embodiment, during the ART game state, stay in one of the modes 1 to 9, and based on a predetermined lottery opportunity, transition between these modes is performed, and the release game for each mode The numbers and the lottery odds for releasing a special small combination called a so-called rare combination are made different. Note that mode 9 is a mode that shifts only when settings are changed.

Specifically, mode 1 is also called normal mode A, and is a mode that is disadvantageous to the player in both the number of unlocked games and the unlocked lottery, but shifts to modes 6 and 7 that are advantageous to the player after unlocking.

Mode 2, also referred to as normal mode B, has the possibility of transitioning from modes other than modes 1, 4, 6, and 7, and has higher transition probability than other modes when transitioning from modes 2, 3, 8, and 9. Is high. Therefore, mode 2 is the mode in which the player stays the most during the game.

Mode 3 is also called pullback mode, and is a mode that shifts to when modes 6 and 7 are completed or when a fixed combination is won in modes 2 and 8, and is advantageous to the player in both the number of unlocked games and the unlocked lottery.

Mode 4 is also referred to as consecutive chan preparation mode, and is a mode in which only one of modes 4 to 7 is transitioned to next time. In particular, it is expected that the player in modes 5 to 7 will be transitioned to an advantageous higher mode next time. mode. In other words, mode 4 is a mode that facilitates transition to modes 5 to 7 next time.

Modes 5 to 7 are also called continuous chan modes A, B, and C, respectively, and are modes in which ART states occur continuously, so-called continuous chan is likely to occur. Modes 5 to 7 are advantageous in terms of both the number of unlocked games and the unlocking lottery. Especially regarding the number of unlocked games, as will be described later, it is confirmed that the mode will be unlocked within 31 games.

Mode 8 is also called high probability mode after setting change, and is a mode that shifts only from mode 9 in which the player stays at the time of setting change.

Mode 9 is also called a setting change mode, and is a mode to which the setting is changed. That is, mode 9 is not entered unless the setting is changed. Further, in the present embodiment, only mode 9 is provided with mode 8 as the next mode transition destination.

[Various data tables related to ART]
37 to 56 show various data tables related to ART stored in the main ROM 32. FIG.

<Mode transition lottery table>
The mode transition lottery tables shown in FIGS. 37 to 45 show the lottery timing when staying in each mode and the modes that can be shifted to the lottery timing.

The lottery timing includes normal cancellation, watermelon cancellation, corner cherry cancellation, cancellation by a fixed combination, cancellation by a middle cherry, and cancellation by a long freeze. Here, normal release indicates release due to reaching the number of released games, or release when "other" wins a release based on the release lottery table (see FIG. 52). Further, the fixed combination refers to the "fixed cherry" and the "fixed small combination" shown in FIG.

Further, watermelon cancellation and corner cherry cancellation refer to cancellation when a cancellation lottery table (see FIG. 52), which will be described later, is used to cancel a winning lottery with a predetermined probability when a double role of watermelon or corner cherry is won.

Also, the confirmed combination and the middle cherry are confirmed to be released when the corresponding internal winning combinations are won in duplicate (see FIG. 52). Therefore, canceling by winning a fixed combination or a middle cherry means canceling by winning a corresponding duplicate combination. Furthermore, release by long freeze means release when long freeze is accompanied by long freeze reservation at the start of the game.

In the present embodiment, as will be described later, a long freeze reservation lottery table (see FIG. 54) at the time of transition to the ART winning state or during the transition to the ART winning state during the ART state, a long freeze reservation lottery table during the ART state (FIG. 56) (see)), the lottery for the long freeze reservation is performed with the winning probability. In addition, in the present embodiment, when the long freeze occurs, release is confirmed regardless of which of the above releases.

As shown in FIG. 37, when the current mode (stay mode) is mode 1, the setting value is common to 1 to 6, and the mode is shifted to mode 6 or mode 7 except for canceling with long freeze. It has become. In mode 1, the probability of transition to mode 6 is set higher than in mode 7.

On the other hand, in the case of canceling with long freeze, only mode 7 is entered. In the case of cancellation accompanied by such a long freeze, not only mode 1 but also modes 2 to 8 other than mode 9 always shift to mode 7 only.

As shown in FIG. 38, when the current mode (stay mode) is mode 2, the mode is shifted to any one of modes 1-7. Mode 2 has a different transition probability for each mode transition destination for each set value, and is set so that the higher the set value, the higher the transition probability to modes 4 and 5, especially for normal cancellation, watermelon cancellation, and square cherry cancellation. It is

As shown in FIG. 39, when the current mode (stay mode) is mode 3, the mode is shifted to any one of modes 1, 2 and 4-7. Mode 3 has a different transition probability for each mode transition destination for each set value, and is set so that the higher the set value is, the higher the probability of transition to modes 4 and 5 is for normal cancellation, watermelon cancellation, and square cherry cancellation. It is

As shown in FIG. 40, when the current mode (stay mode) is mode 4, the mode is shifted to any one of modes 1 and 4-7. Mode 4 has a different transition probability for each mode transition destination for each set value, and is set so that the higher the set value is, the higher the probability of transition to mode 5 is, especially for normal cancellation, watermelon cancellation, and square cherry cancellation. there is

As shown in FIG. 41, when the current mode (stay mode) is mode 5, the mode is shifted to any one of modes 1, 2 and 4-7. In this mode 5, the probability of transition to each mode transition destination at the time of normal cancellation differs for each set value. It's set to be less likely.

As shown in FIG. 42, when the current mode (stay mode) is mode 6, the mode is shifted to any one of modes 3, 6 and 7. FIG. In mode 6, the probability of transition to each mode transition destination at the time of normal cancellation differs between set values 1 to 4, 6 and set value 5, and only when the set value is 5, the probability of transition to mode 7 is different. While it is higher than the set value, it is set so that the probability of transition to mode 6 is low.

As shown in FIG. 43, when the current mode (stay mode) is mode 7, setting values 1 to 6 are common, and the mode is shifted to either mode 3 or 7. FIG. This mode 7 is set so as to shift to mode 3 only when the normal mode is canceled.

As shown in FIG. 44, when the current mode (stay mode) is mode 8, the mode is shifted to any one of modes 1-7. This mode 8 has a different transition probability for each mode transition destination for each set value, especially in normal cancellation, watermelon cancellation, and corner cherry cancellation, the higher the set value, the higher the probability of transition to modes 4 and 5. It is

As shown in FIG. 45, when the current mode (stay mode) is mode 9, the mode is shifted to any one of modes 1, 2, 4 and 8. FIG. The lottery trigger for mode 9 is when the setting is changed, and the transition probability of each mode transition destination differs according to the setting value after the setting change. For example, it is set such that the higher the set value after the setting change, the higher the probability of transition to mode 8.

<Lottery table for the number of unlocked games>
The unlocked game number lottery tables shown in FIGS. 46 to 51 show the distribution of the unlocked game number when staying in each mode.

The number of unlocked games is the number of games ( number of games) is defined in advance.

It should be noted that when the setting is changed, the number of unlocked games described above starts with the next game after the setting is changed. Therefore, in this embodiment, after the end of the ART state or after the setting is changed, when the specified number of unlocked games is completed, that is, when the number of games corresponding to the predetermined number of unlocked games is played, the ART is forced. The game state shifts from the normal game state to the ART winning state.

In the present embodiment, the number of unlocked games is between 0 and 1051, between a specific number of games (eg 0 game, 31 game, etc.) and a predetermined number of games (eg, 32 game to 63 game, etc.). distributed.

Such a distribution probability of the number of released games differs depending on the stay mode and set value.
The number of unlocked games can be arbitrarily set, and is not limited to the number of games described above, and the distribution range can be changed as appropriate.

As shown in FIG. 46, when the current mode (stay mode) is mode 1, the number of unlocked games is distributed to 951 or more games in common for set values 1 to 6, and the number of unlocked games is 950 or less. It cannot be divided into numbers.

As shown in FIG. 47, when the current mode (stay mode) is mode 2, the number of unlocked games is distributed from a relatively short number of games to a relatively long number of games based on the distribution ratio shown in FIG. there is

Also, in Mode 2, the distribution ratio of the number of unlocked games is slightly different for each set value. is set to

As shown in FIG. 48, when the current mode (stay mode) is mode 3, the number of unlocked games is distributed to 31 games in common for set values 1 to 6, and the number of unlocked games other than 31 games is will not be allocated to

As shown in FIG. 49, when the current mode (stay mode) is mode 4, the number of unlocked games is distributed from a relatively short number of games to a relatively long number of games based on the distribution ratio shown in FIG. there is

Also, in Mode 4, the distribution ratio of the number of unlocked games is slightly different for each set value. is set to

As shown in FIG. 50, when the current mode (stay mode) is one of modes 5 to 7, the set values 1 to 6 are common, and the number of released games is divided into 0 games or 31 games. Alternatively, the number of unlocked games other than 31 games is not assigned.

Here, in modes 5 to 7, the distribution rate for the 31st game is set to be higher than the distribution rate for the 0th game.

As shown in FIG. 51, when the current mode (stay mode) is mode 8, the set values 1 to 6 are common, and the number of unlocked games is divided into 32 games to 95 games. It is not distributed to the number of unlocked games other than games.

Here, in mode 8, the distribution rate for the 64th to 95th games is set to be higher than the distribution rate for the 32nd to 63rd games.

<Release lottery table>
The release lottery table shown in FIG. 52 shows the release probability for each internal winning combination for each mode (modes 1 to 8). It should be noted that the release probability means the probability of winning the release in FIG.

As shown in FIG. 52, in the present embodiment, as internal winning combinations that may be canceled in the present embodiment, a special combination (watermelon, square cherry, fixed combination and middle cherry) and a combination of multiple combinations excluding the special combination ( others) are listed. Here, the fixed combination and the middle stage cherry are confirmed to be released at the time when they are extracted as an internal winning combination in any of the modes 1 to 8 and in any of the set values.

As for the other internal winning combinations, the release probabilities are set differently for each of the modes 1 to 8. FIG. For example, in mode 1, the release probability is set to decrease in the order of watermelon, horn cherry, and others, while in mode 7, the release probability is set to decrease in the order of watermelon, horn cherry, and others. . It should be noted that other internal winning combinations related to cancellation refer to internal winning combinations other than watermelon, square cherry, fixed combination, and middle cherry that may be canceled.

<Short freeze lottery table when transitioning to ART winning state>
The short freeze lottery table at the time of ART winning state transition shown in FIG. be.

In this short freeze lottery table at the time of transition to ART winning state, depending on which of the number of games cancellation, watermelon cancellation, corner cherry cancellation, fixed combination cancellation, middle cherry cancellation and other cancellation, the transition to ART winning state is made, The probability of being determined is different when performing a short freeze.

For example, the probability of short freezing is set to be the highest when corner cherry is canceled and the lowest when watermelon is canceled.

<Long freeze reservation lottery table when transitioning to ART winning state>
The long freeze reservation lottery table at the time of ART winning state transition shown in FIG. is a table.

In this long freeze reservation lottery table at the time of transition to ART winning state, it depends on which of the number of games cancellation, watermelon cancellation, corner cherry cancellation, fixed combination cancellation, middle cherry cancellation and other cancellation, the transition to the ART winning state is triggered. , the probability of being determined to make a long freeze reservation is different.

For example, the probability of making a reservation for a long freeze is set to be the highest when canceling the middle stage cherry, and the lowest when canceling the number of games and others.

<Announcement mode lottery table when transitioning to ART winning state>
The notification mode lottery table at the time of transition to the ART winning state shown in FIG. is a table referenced by

The above-mentioned notification mode means that when either of the bonus lips 1 and 2 is internally won during the ART winning state, a notification by the notification unit 111 (see FIG. 6) imitating a hibiscus pattern provided on the front panel 110 is performed. This is the mode for deciding whether to perform or not.

Specifically, the notification mode 1 is a mode in which the notification unit 111 makes a notification with a probability of 100% when any of the bonus replies 1 and 2 is internally won during the ART winning state.

The notification mode 2 is a mode in which the notification unit 111 makes a notification with a probability of 50% when either bonus reply 1 or 2 is internally won during the ART winning state.

In addition, the notification mode 3 is a mode in which the notification unit 111 makes a notification with a probability of 25% when any of the bonus replies 1 and 2 is internally won during the ART winning state. Thus, in the present embodiment, the probability of notification by notification unit 111 (notification probability) is made different for each mode.

ART winning state transition notice mode lottery table, the announcement mode lottery opportunity is when the number of games is canceled, when the watermelon is canceled, when the corner cherry is canceled, when the fixed combination is canceled, when the middle cherry is canceled, when other cancellations are made, and when long freezes are canceled. time is mentioned.

In this notification mode lottery table at the time of transition to the ART winning state, the distribution rate of each notification mode is different depending on the lottery timing. It is

In addition, in the case of other cancellations, notification mode 1 and notification mode 2 are set to be distributed with the same probability. Furthermore, in the case of cancellation of corner cherry, the distribution rate of notification mode 1 is the highest, followed by notification modes 2 and 3 with the same probability.

<Long freeze reservation lottery table during ART>
The long freeze reservation lottery table during ART shown in FIG. This table is referenced to determine whether or not to reserve a freeze.

In this ART long freeze reservation lottery table, the probability of making a long freeze reservation at the next ART state transition is the highest when the middle cherry is internally won, and the lowest when the square cherry is internally won. is set.

[Various data tables on the sub-control side]
57 to 60 are various data tables stored in the sub ROM 82. FIG.

<ART type notification distribution lottery table>
The lottery table for ART type notification distribution shown in FIG. This is a table for determining distribution of notification as to whether BB or RB is to be won by notifying the stop operation order when an internal prize is won.

Also, in this ART type notification distribution lottery table, the distribution ratios of BB and RB descriptors are set differently based on the timing of lottery and the current mode (stay mode). There are a plurality of lottery opportunities here depending on the type of release at the time of transition from the normal game state to the ART winning state in the ART game state, and (other than 0) release, 0 game release, watermelon release, corner cherry release, fixed role There are release, middle cherry release and other release.

In detail, the transition from the normal game state to the ART winning state in the ART game state is any of the number of games (other than 0) cancellation, 0 game cancellation, watermelon cancellation, square cherry cancellation, fixed combination cancellation, middle cherry cancellation and other cancellations. The distribution rate of BB and RB lips differs depending on whether or not it was done by releasing the . For example, when the lottery opportunity is 0 game cancellation, fixed combination cancellation, or mid-stage cherry cancellation, the stop operation order for winning BB lips with a probability of 100% is notified.

Also, as described above, the rate of distribution of BB and RB descriptors differs depending on the stay mode. In the case of other cancellations, it is set so that the distribution rate of the RB reply is higher than that of the BB reply.

<Normal navigation lottery table>
The normal navigation lottery table shown in FIG. 58 is referred to when determining the navigation data during ART state based on the internal winning combination when the BB malfunction flag is off in the start command reception process shown in FIG. It is a table where

The navigation data during ART is data for informing the player of the pressing order of the stop buttons 7L, 7C, and 7R, that is, the order of stop operation. There are "middle", "middle left and right", "middle right left", "right left middle" and "right middle left". In addition, "no notification" is included in this ART navigation data.

In the normal navigation lottery table, for example, in the case of the internal winning combination (lower bell) corresponding to the winning numbers 4 to 6, the navigation data in the ART is "center left and right", "center right left", "right left center" and "right center left". ” are set to be distributed with the same probability.

Here, as shown in FIG. 20, the internal winning combination (lower bell) corresponding to winning numbers 4 to 6 is correctly pressed when the stop button 7C or 7R is pressed as the first stop operation. Therefore, in this normal navigation lottery table, the internal winning combination (lower bell) of the internal winning combination (lower bell) as navigation data in ART is not sorted into stop operation orders ("left center right" and "left center right") that are incorrect. It is supposed to be.

In addition, in the case of the internal winning combination (middle bell) corresponding to the winning numbers 7-12, 13-18, 19-24, 25-30, the stop operation order that is the correct stop operation order as navigation data in ART It is set to be distributed with a probability of 100%.

For example, in the internal winning combination (middle bell) corresponding to winning numbers 7 to 12, as shown in FIG. It will be distributed according to probability.

<Special navigation lottery table>
The special navigation lottery table shown in FIG. 59 is referred to when determining the navigation data during ART state based on the internal winning combination when the BB malfunction flag is ON in the start command reception process shown in FIG. It is a table where

The special navigation lottery table is different from the normal navigation lottery table. In addition to "middle" and "right middle left", the stop operation order of "left middle right" is set to be distributed with a predetermined probability.

Therefore, in this special navigation lottery table, there are times when navigation data in ART is sorted into the stop operation order ("left, middle, right") that is incorrect in the stop operation order of the internal winning combination (lower bell). . As a result, the profit (here, the number of medals obtained by ART) given to the player when the player wins BB1 or BB2 by mistake or intentionally instead of activating the RB is adjusted.

Similarly, in the case of internal winning combinations (middle bell) corresponding to winning numbers 7 to 12, 13 to 18, 19 to 24, and 25 to 30, stop operation is not allowed other than the correct stop operation order. It is set so that the correct stop operation order is also sorted with a predetermined probability.

For example, in the internal winning combination (middle bell) corresponding to winning numbers 7 to 12, the correct stop operation order is "middle left and right" as shown in FIG. The stop operation order of "middle right left", "right left middle", and "right middle left" is also sorted with a predetermined probability.

However, even in this case, since it is necessary to give the player at least the profit from the RB that should have been won, It is set so that the probability of being assigned to the stop operation order of "center left and right", which is the correct stop operation order, is relatively higher than the probability of being assigned to the stop operation order of "center left". The same applies to internal winning combinations corresponding to winning numbers 4-6 and 13-30.

<Unauthorized navigation lottery table>
In the illegal navigation lottery table shown in FIG. 60, when the BB malfunction flag is ON and a sequence error occurs in the start command reception processing shown in FIGS. This table is referred to when determining navigation data during ART.

The illegal navigation lottery table is different from the normal navigation lottery table and the special navigation lottery table. It is set to be distributed with a probability of

Therefore, in this fraudulent navigation lottery table, even if the internal winning combination (lower bell) is won as the navigation data in ART, it is distributed so that the stop operation is not notified. As a result, the sub CPU 81 intentionally causes BB1 or BB2 to win when RB should be activated, and momentarily powers off any or all of the boards that make up the pachislot machine 1, which is a so-called power-off goto, or a main power supply. Since there is a high possibility that a sequence error has occurred due to a fraudulent act that temporarily disconnects the communication between the control circuit 71 and the sub-control circuit 72, that is, a so-called line disconnection state, the player (here, the number of medals acquired by ART) is adjusted.

Similarly, internal winning combinations (middle bell) corresponding to winning numbers 7-12, 13-18, 19-24, and 25-30 are set so as to be distributed so that the stop operation is not notified. .

However, a sequence error also occurs when an error occurs during communication between the main control circuit 71 and the sub-control circuit 72 other than by the player's fraudulent act. It is configured to be distributed with a probability of 100% to the stop operation order of "left, middle, right" where normal replies win prizes.

<Sound list table>
The sound list tables shown in FIGS. 61 and 62 are referred to in each subflow of the sound control task shown in FIG. 92 when determining the sound effect corresponding to the effect number determined by each lottery process.

The sub CPU 81 uses the effect number determined by each lottery process or control process and the sound list table shown in FIGS. cmd No) is transferred from the sub-ROM 82 to the DSP 84, and sound effects are executed.

As shown in FIGS. 61 and 62, each command number includes a wav file name indicating the file name of the sound data stored in the sub ROM 82, each parameter related to each sound data, and the execution time of each sound data. and a type indicating the sound type of each sound data are set.

The wav file name is the file name of sound data stored in the sub ROM 82 . When executing each sound effect, the sub CPU 81 transfers the sound data of the file name set to each command number from the sub ROM 82 to the DSP 84 and reproduces it by the speakers 9L and 9R. Here, in the present embodiment, all sound data are saved in wav format. Note that this is an example, and the present invention is not limited to this.

Each parameter associated with the command number includes the channel (CH) of the digital amplifier 87, the sound data transfer rate (kbps), and the loop and chain that are the reproduction pattern of the sound data. It is configured.

Of the parameters associated with the command number, the channel (CH) is a parameter that indicates the output channel to the digital amplifier 87 . Here, in the pachi-slot machine 1 according to the present embodiment, the digital amplifier 87 has six channels, which are set as CH1 to CH6.

For example, when the sub CPU 81 executes a sound effect based on a command number having "1" as CH and a sound effect based on a command number having "2" as CH, CH1 and CH2 of the digital amplifier 87 are set to each channel. It is configured to input corresponding sound data, and execute a sound presentation in which the digital amplifier 87 reproduces the sound obtained by synthesizing the sound data input to CH1 and the sound data input to CH2.

Here, when continuous sound data is input to the same channel, the sub CPU 81 can output the sound data input to the predetermined channel later even while the sound data first input to the predetermined channel is being output. It is configured to overwrite the first input sound data with data, and reproduce the later input sound data from the speakers 9L and 9R.

Among the parameters associated with the command numbers, the transfer rate (kbps) of the sound data is the transfer rate (kbps) of the sound data associated with each command number from the DSP 84 to the speakers 9L and 9R in one second. This is a parameter that indicates the file capacity that can be used.

Among the parameters associated with the command numbers, Loop indicates whether or not to perform so-called loop playback, which is performed again after the sound data associated with each command number is executed. is a parameter indicating

Among the parameters associated with command numbers, Chain indicates whether or not other sound data is to be continuously executed after the sound data associated with each command number is executed. It is a parameter that indicates whether

Volume is associated with sound volume when sound data associated with each command number is executed. The sub CPU 81 transfers the set volume value to the digital amplifier 87 when executing the sound data associated with each command number.

The type is a value used in the sound-related data initialization process (see FIG. 93) and the sound effect execution process (see FIG. 95), and consists of type "1" and type "2".

Here, the sound data set to type "1" constitutes specific effect information in this embodiment, and is transferred from the sub ROM 82 to the audio RAM 85 in the process of initializing the sound-related data. Sound data set to type "1" is executed after being transferred from the audio RAM 85 to the DSP 84 in the sound effect execution process. Also referred to as "file".

In addition, since the sound data set to type "2" is sound data that is executed while being transferred from the sub ROM 82 to the DSP 84 in the sound effect execution process, that is, so-called streaming reproduction is performed, in the following description, Type "2" is also described as "stream" as a sound type.

Further, in the present embodiment, sound data set to type "1" is sound data that is played more frequently than sound data set to type "2".

The command content describes the content of sound data associated with each command data. For example, when the gaming state is the normal state and the BET operation is executed, the sub CPU 81 transfers the sound data associated with the command number “103” from the sub ROM 82 to the DSP 84, and executes sound effects. Therefore, "[Normal] bet" is set as the command content of the command number "103".

In this embodiment, each sound data is configured to be executed by the DSP 84 until the reproduction thereof is completed.

<Sound sequence table>
The sound sequence table shown in FIG. 63 is a table referred to by the sub CPU 81 in the sound data analysis process shown in FIG. 94 and the sound effect execution process shown in FIG. 95 when a predetermined condition is satisfied.

As shown in FIG. 63, the sound sequence table has execution conditions set for each sequence number corresponding to each sound sequence. Each command number to be executed by the command number, the presence or absence of loops and chains, and the execution trigger (Trigger) of the sound effect associated with the command number are set. Here, the execution condition set for each sequence number constitutes a predetermined condition in this embodiment.

The sub CPU 81, for example, causes the player to perform the first stop operation on the left stop button 7L, the second stop operation on the middle stop button 7C, and the third stop operation on the right stop button 7R. Sequence number "1" is selected when "replay navigation (left center right)", which is navigation, is executed.

When the sequence number "1" is selected, the sub CPU 81 executes the sound effect corresponding to the command number "176" in the sound list table (see FIGS. 61 and 62), using the turn-on of the start switch 6S as an execution trigger. , and with the execution of the first stop operation as the execution trigger, execute the sound effect corresponding to the command number "177" in the sound list table, and with the execution of the second stop operation as the execution trigger, It is configured to execute a sound effect corresponding to command number "178" in the sound list table.

In the present embodiment, the sound sequence table is composed of fixed-length tables with sequence numbers 1 to 14 and sequences 1 to 3. However, the present invention is not limited to this. It may be a table of variable length.

Further, in the present embodiment, as shown in FIG. 63, the sub ROM 82 stores a sound sequence as a group of effect information composed of a plurality of sound data set in a sound sequence table as a plurality of predetermined effect information. , constitutes performance information group storage means.

<LED/sound output list table>
The LED/sound output list table shown in FIG. 64 is a table referred to when determining LED effect data corresponding to sound effects in each subflow of the LED output control task shown in FIG.

The sub CPU 81 refers to the effect number determined by each lottery process or control process and the LED/sound output list table shown in FIG. Executes a lighting effect that emits light.

Here, the pachi-slot machine 1 according to the present embodiment includes a dot display device 100 (see FIG. 3), a reel effect display device 103 (see FIG. 3), a side effect display device 104 (see FIG. 3), and a light emitting The part 330 (see FIG. 5) is the target part to emit light.

As shown in FIG. 64, each LED effect data is associated with an LED number (LED No.). Each LED number is associated with a command number. Here, each command number represents a command number set in the sound list table shown in FIGS.

Further, the LED/sound output list table includes LED numbers associated with common command numbers. For example, command number "201" is associated with three LED numbers "21", "33", and "34". The sub CPU 81 normally executes the sound effect associated with the command number "201" as the sound effect when the BB wins. Since "Red 7-Red 7" is displayed, LED number "21" and LED number "33" are executed.
Further, when the sub CPU 81 wins the BB Lip 2, the display line 8e (see FIG. 3) displays "red 7-red 7-red 7", so that the LED number "21" and the LED number "33" are displayed. ”.

In addition, as shown in FIG. 64, the LED effect data associated with each LED number is set as a condition to be executed so that it is executed when various states occur. (See FIG. 90), when the sound effect is being executed but the LED effect data related to the sound effect being executed is not executed, the LED effect data is configured to be executed. there is

As shown in FIGS. 61 to 64, in the present embodiment, a sub ROM 82 for storing sound data and LED effect data as a plurality of effect information to be executed according to the progress of the game constitutes effect information storage means. do.

[Main control process]
The main CPU 31 of the main control circuit 71 executes various processes according to the flow charts shown in FIGS.

<Main control processing>
FIG. 65 is a flowchart showing main control processing. It should be noted that the main control process described below starts when the pachi-slot machine 1 is powered on.

First, when the pachi-slot machine 1 is powered on, the main CPU 31 executes power-on processing shown in FIG. 66 (S10). In this power-on process, it is determined whether the backup is normal, whether the setting has been changed appropriately, and the like, and the initialization process is executed according to the determination result.

Next, the main CPU 31 executes an initialization process at the end of one game (1 unit game) (S11). In this initialization process, for example, a storage area designated in advance to be initialized at the end of one game is initialized. By this initialization process, the data stored in the internal winning combination storing area and the display combination storing area of the main RAM 33 are cleared.

Next, the main CPU 31 executes medal acceptance/start check processing shown in FIG. 67 (S12). In this medal acceptance/start check process, a process of detecting medals inserted by the player and a process of detecting a start operation are executed.

Next, the main CPU 31 extracts three random numbers (random numbers 1 to 3) and stores them in the random number storage area assigned to the main RAM 33 (S13). Here, the random value 1 is a value used for internal lottery processing, and is extracted from 0 to 65535 in this embodiment.

Random numbers 2 and 3 are values used for other lottery processing, and are extracted from 0 to 65535 and 0 to 255, respectively, in the present embodiment. It should be noted that the main CPU 31 does not need to extract the random numbers 2 and 3 in step S13, and may extract the random numbers 2 and 3 when using them.

Next, the main CPU 31 executes internal lottery processing shown in FIG. 68 (S14). The main CPU 31 that executes this internal lottery process constitutes internal winning combination determining means.

Next, the main CPU 31 executes the ART gaming state lottery process shown in FIG. 69 (S15). This ART gaming state lottery processing includes lottery processing relating to the transition of the ART gaming state, lottery processing of whether or not to set on a flag referred to in each ART gaming state, and the like.

Next, the main CPU 31 executes reel stop initial setting processing shown in FIG. 73 (S16). By this reel stop initial setting process, each piece of information (for example, stop table number, etc.) related to the reel stop control is stored in the relevant area of the main RAM 33 based on the result of the internal lottery process (internal winning combination).

Next, the main CPU 31 generates start command data to be transmitted from the main control circuit 71 to the sub-control circuit 72, and stores the generated start command data in the communication data storage area assigned to the main RAM 33 (S17).

The start command data represents, for example, the type of the game state flag, the value of the bonus end number counter, the type of the internal winning combination, the type of the flag related to lock, etc., and the value of the timer for effect.

Next, the main CPU 31 executes the game start freeze process shown in FIG. 74 (S18). In this game start freeze process, freezing is executed based on various flags referred to in each ART game state.

Next, the main CPU 31 executes wait processing (S19). In this wait process, it is determined whether or not a predetermined time has passed since the start of the previous game (start of the previous unit game). If it is determined that the predetermined time has not passed, the predetermined time has passed. Wait until the waiting time is digested. The predetermined time in this wait process, that is, the wait time is set to 4.1 seconds from the start of the previous unit game, for example.

Next, the main CPU 31 executes reel rotation processing for rotating all the reels 3L, 3C, and 3R according to the number of inserted medals (S20). Along with this reel rotation start processing, "01110000" is stored in the operation stop button storage area (see FIG. 31). Also, the reel rotation start process is executed by the interrupt process shown in FIG. This interrupt processing is processing executed at a constant cycle (1.1172 ms).

By this interrupt processing, the driving of the stepping motors 49L, 49C and 49R is controlled, and the rotation of the reels 3L, 3C and 3R is started. Thereafter, this interrupt process controls the drive of the stepping motors 49L, 49C and 49R to accelerate the rotation of the reels 3L, 3C and 3R until they reach a constant speed.

Furthermore, when the rotation of the reels 3L, 3C and 3R reaches a constant speed, this interrupt processing controls the driving of the stepping motors 49L, 49C and 49R so that the reels 3L, 3C and 3R rotate at a constant speed. maintained.

Next, the main CPU 31 generates reel rotation start command data to be transmitted from the main control circuit 71 to the sub-control circuit 72, and stores the generated reel rotation start command data in the communication data storage area allocated to the main RAM 33 ( S21).

By receiving this reel rotation start command data, the sub-control circuit 72 can recognize the start of reel rotation, and can determine the timing for executing various effects.

Next, the main CPU 31 executes attraction priority storage processing (S22). In this attraction priority storage process, the attraction priority table selection process shown in FIG. 77 is executed to determine the attraction priority of all symbols on the rotating reels 3L, 3C, and 3R. That is, in the attraction priority storing process, stop information is stored in the attraction priority data storage area for each symbol position of each spinning reel based on the internal winning combination.

For example, for each symbol on each of the reels 3L, 3C, and 3R, if the corresponding symbol is permitted to stop, the attraction priority data is stored in the attraction priority data storage area based on the priority table, and the stop is not allowed. In the case of permission (for example, when a combination that has not been won wins), data indicating stop prohibition is stored in the attraction priority data storage area.

Next, the main CPU 31 executes reel stop control processing shown in FIG. 78 (S23).
By this processing, stop control of the reels 3L, 3C, and 3R is performed. Next, the main CPU 31 executes winning search processing (S24).

In this winning search process, after all the reels 3L, 3C and 3R are stopped, the symbol combination displayed on the winning line 8c is compared with the symbol combination table, and the symbol combination displayed on the winning line 8c is determined. be.

Specifically, the data stored in the symbol code storage area (see FIG. 30) and the data in the symbol combination table (see FIGS. 15 to 17) are collated, and the result of the collation is the display combination storage area (see FIG. 29). reference).

More specifically, data in the symbol code storage area is copied as it is to the display combination storage area. At that time, the number of payouts is obtained by referring to the symbol combination table. Through this winning search process, a combination of symbols displayed on the display windows 4L, 4C, 4R when all the reels 3L, 3C, 3R are stopped is specified.

Next, the main CPU 31 executes payout of the number of medals according to the displayed symbol combination based on the result of the winning search process (S25). Along with this medal payout process, the hopper driving circuit 41 is controlled and the number of credits is updated based on the payout number counter.

Next, the main CPU 31 executes ART-related processing shown in FIG. 80 (S26). The ART-related processing includes processing for managing the number of games related to the ART gaming state, setting flags referred to in each ART gaming state, and the like.

Next, the main CPU 31 executes the game end lock process shown in FIG. 81 (S27). In this game end lock process, locking is executed based on various flags referred to in each ART game state.

Next, the main CPU 31 generates prize-winning operation command data to be transmitted from the main control circuit 71 to the sub-control circuit 72, and stores the generated prize-winning operation command data in the communication data storage area allocated to the main RAM 33 (S28). . The winning actuation command data represents, for example, the type of display combination, a flag relating to locking, etc., the number of payout medals, and the like.

Next, the main CPU 31 executes bonus end check processing shown in FIG. 82 (S29). By this bonus termination check process, a process of terminating the operation of the MB is executed when the termination condition of the MB is satisfied.

Next, the main CPU 31 executes bonus operation check processing shown in FIG. 83 (S30). By this bonus operation check process, a process of operating the MB based on the combination of symbols displayed by the reels 3L, 3C and 3R is executed. After executing the process of step S30, the main CPU 31 executes the process of step S11.

<Processing when power is turned on>
FIG. 66 is a flow chart showing power-on processing executed in step S10 of the main control processing shown in FIG.

First, the main CPU 31 determines whether or not the backup is normal (S40).
In this determination process, it is determined whether or not the backup is normal by error detection using the checksum value.

For example, the main CPU 31 stores the setting values of the pachi-slot machine 1 and the checksum value calculated from the setting values in the main RAM 33 as backup data when the power is turned off, and performs the determination process when the power is turned on (S40). , the setting values and the checksum value stored in the main RAM 33 are read.

Then, the main CPU 31 compares the checksum calculated from the read setting values and the backed up checksum, and determines that the backup is normal if the comparison results match.

When the main CPU 31 determines that the backup is normal (YES), the main CPU 31 sets the backed up setting values (S41). As a result, if the backup is normal, the set value before the power is turned off is set.

After executing the process of step S41, or when it is determined that the backup is not normal in step S40 (NO), the main CPU 31 turns on the setting change switch provided in the cabinet 60 of the pachi-slot machine 1. (S42). Here, when the main CPU 31 determines that the setting change switch is on (YES), the main CPU 31 executes initialization processing when changing the setting (S43).

In the initialization process at the time of setting change, for example, the data stored in the internal winning combination storing area and the display combination storing area of the main RAM 33 are cleared, and the set values are cleared.

Subsequently, the main CPU 31 sets the release mode stored in the main RAM 33 to mode 9, and clears the number of released games stored in the main RAM 33 to 0 (S44). Next, the main CPU 31 generates initialization command data to be transmitted from the main control circuit 71 to the sub-control circuit 72, and stores the generated initialization command data in the communication data storage area allocated to the main RAM 33 (S45). . The initialization command data indicates, for example, whether or not the setting value has been changed, the setting value, and the like.

Next, the main CPU 31 executes set value change processing (S46). In this set value change process, the set value is selected from among 1 to 6 according to the operation result of the reset switch, and the set value selected when the start lever 6 which is subsequently operated is operated. confirms.

Next, the main CPU 31 determines whether or not the setting change switch is in the ON state (S47), and repeats the process of step S47 until it is determined that the setting change switch is not in the ON state.

Here, if it is determined that the setting change switch is not in the ON state (NO), it means that the setting value change process has been completed. , referring to the mode transition lottery table (see FIGS. 37 to 45), based on the current release mode, the set value, the lottery trigger, and the random value 3, the release mode of the transition destination, that is, the transition destination mode is determined (S48).

Next, the main CPU 31 refers to the unlocked game number lottery table (see FIGS. 46 to 51), and determines the unlocked game number based on the unlock mode, set value, and random number 3 (S49). Here, when the main CPU 31 determines the number of unlocked games represented by a range such as "0 to 31" as the number of unlocked games, the main CPU 31 randomly determines one number of unlocked games from within this range. do.

Next, the main CPU 31 generates initialization command data to be transmitted from the main control circuit 71 to the sub-control circuit 72, and stores the generated initialization command data in the communication data storage area allocated to the main RAM 33 (S50). , terminate the power-on processing.

When the main CPU 31 determines in step S42 that the setting change switch is not on (NO), it determines whether or not the backup is normal (S51). Here, if it is determined that the backup is not normal (NO), the main CPU 31 executes power-on error processing (S52).

In the power-on error processing, the main CPU 31 indicates that the backup is not normal by displaying an error or the like. In addition, the main CPU 31 does not release the error state depending on the operation of the stop release switch or the reset switch in the state of an error (backup error) in which the backup is not normal. The error state is cleared only when

In step S51, when it is determined that the backup is normal (YES), the main CPU 31 restores the state of the pachi-slot machine 1 to the state before the power was turned off based on the backup data stored in the main RAM 33. (S53), the power-on process is terminated.

<Medal reception/start check processing>
FIG. 67 is a flow chart showing the medal acceptance/start check process executed in step S12 of the main control process shown in FIG.

First, the main CPU 31 determines whether or not there is an automatic input request (S60). If the replay combination was won in the previous unit game, medals are automatically inserted in the current unit game. That is, in the determination process of step S60, it is only necessary to determine whether or not the replay combination was won in the previous unit game.

In step S60, when the main CPU 31 determines that there is an automatic insertion request (YES), it executes automatic insertion processing for automatically inserting the same number of medals as the medals inserted in the previous unit game (S61). Specifically, the main CPU 31 copies the automatic insertion counter to the insertion number counter, and clears the automatic insertion counter.

Subsequently, the main CPU 31 generates medal insertion command data to be transmitted from the main control circuit 71 to the sub-control circuit 72, and stores the generated medal insertion command data in the communication data storage area allocated to the main RAM 33 (S62). . Here, the medal insertion command data indicates, for example, the presence or absence of insertion of medals, the value of the insertion number counter, the value of the credit counter, and the like.

When the main CPU 31 determines in step S60 that there is no request for automatic insertion (NO), it permits receipt of medals (S63). For example, the main CPU 31 drives a solenoid of a selector (not shown) to form a path so that medals inserted into the medal slot 22 pass through the selector.

In step S60, when the main CPU 31 determines that there is an automatic insertion request (YES), the reception of medals has been prohibited since the previous unit game. does not run.

After the process of step S62 or S63 is executed, the main CPU 31 sets the maximum number of inserted coins according to the game state (S64). In this embodiment, three cards are set in the main game state other than the MB game state, and two cards are set in the MB game state.

Next, the main CPU 31 determines whether acceptance of medals is permitted (S65). Here, when it is determined that acceptance of medals is permitted (YES), the main CPU 31 executes medal insertion check processing for checking the number of inserted medals (S66). In this medal insertion check process, the value of the inserted number counter is updated according to the number of medals checked.

Subsequently, the main CPU 31 generates medal insertion command data to be transmitted from the main control circuit 71 to the sub-control circuit 72, and stores the generated medal insertion command data in the communication data storage area assigned to the main RAM 33 (S67). .

Next, the main CPU 31 determines whether or not medals can be inserted or credit can be given (S68). In this embodiment, the main CPU 31 determines that the number of inserted cards is 3 in the main game state other than the MB game state, and 2 in the MB game state, and the credit is 50, or Under the condition that the automatic insertion process of step S61 has been executed, it is determined that medal insertion or credit is not possible when the condition is satisfied, and medal insertion or credit is possible when the condition is not satisfied. to decide.

If it is determined in step S68 that medals cannot be inserted or credited (NO), the main CPU 31 prohibits medal reception (S69). For example, the main CPU 31 forms a path through which the medals inserted into the medal slot 22 are ejected from the medal payout slot 15 without driving the solenoid of the selector.

If it is determined in step S65 that acceptance of medals is not permitted (NO), if it is determined that medals can be inserted or credited in step S68 (YES), or after the processing of step S69 is executed , the main CPU 31 determines whether or not the number of inserted medals is sufficient to start a game (S70).

That is, the main CPU 31 determines whether or not the number of inserted medals is sufficient to start the unit game according to the game state. In this embodiment, the main CPU 31 determines whether or not the number of inserted medals is three when the main control game state is a game state other than the MB game state. Determine whether or not

Here, when determining that the number of inserted medals is not enough to start the game (NO), the main CPU 31 executes the process of step S65. On the other hand, when determining that the number of inserted medals is sufficient to start the game (YES), the main CPU 31 determines whether or not the start switch 6S is on (S71).

Here, when determining that the start switch 6S is not on (NO), the main CPU 31 executes the process of step S65. On the other hand, when determining that the start switch 6S is on (YES), the main CPU 31 prohibits medal reception (S72), and ends the medal reception/start check process.

<Internal lottery processing>
FIG. 68 is a flow chart showing internal lottery processing executed in step S14 of the main control processing shown in FIG.

First, the main CPU 31 determines whether or not the main game state is the MB game state (step S80). This determination process is executed based on whether bit 0 of the game state flag storage area corresponding to the MB game state is "1" by referring to the game state flag storage area (see FIG. 34).

That is, when the bit 0 of the game state flag storage area is "1", it is determined that the main game state is the MB game state, and when the bit 0 of the game state flag storage area is "0". , it is determined that the main game state is not the MB game state.

Here, when the main CPU 31 determines that the gaming state is the MB gaming state (YES), the main CPU 31 executes processing during MB operation (S81). In the MB operation process, bits corresponding to all minor combinations in the internal winning combination storing area (see FIG. 28), that is, all bits in the internal winning combination storing area 4 to 11 and 0 to 4 in the internal winning combination storing area 12 All bits are updated to "1". After executing the MB in-operation process, the main CPU 31 terminates the internal lottery process.

On the other hand, in step S80, when the main CPU 31 determines that the main game state is not the MB game state (NO), it sets an internal lottery table corresponding to the main game state (S82).

In the present embodiment, the main CPU 31 sets the internal lottery table for the general game state (see FIG. 18) when the main game state is the normal game state, and sets the internal lottery table for the normal game state (see FIG. 18), sets the internal lottery table for the RT1 gaming state (see FIG. 19).

Next, the main CPU 31 acquires the random value 1 stored in the random value storage area (S83). Next, the main CPU 31 refers to the predetermined area of the internal lottery table set in step S82, and determines the lottery value associated with each winning number (1 to 36 in this embodiment) of the corresponding set value. are obtained one by one, and the lottery value is subtracted from the random value 1 (S84).
That is, the main CPU 31 collates internal winning combinations.

Next, the main CPU 31 determines whether or not the result of the subtraction in step S84 is smaller than 0 (S85). Here, if the main CPU 31 determines that the subtraction result is not less than 0 (NO), that is, if it determines that so-called borrowing is not performed, it updates the random value 1 and the winning number (S86). ).

Next, the main CPU 31 determines whether or not all the winning numbers in the internal lottery table being used have been checked (S87), and if it determines that all the winning numbers have not been checked (NO). , the process of step S84 is executed.

On the other hand, when the main CPU 31 determines that all the winning numbers have been checked (YES), it sets 0 as the value of the data pointer (S88). In the present embodiment, the internal lottery table for the normal game state and the internal lottery table for the RT1 game state are set so that the subtraction result will not be 0 or more when the main CPU 31 finishes checking all the winning numbers. Therefore, step S88 is not executed.

In step S85, if the main CPU 31 determines that the result of the subtraction is less than 0 (YES), that is, if it determines that a so-called borrowing has been performed, the internal lottery table that has been set is referred to and the winning number is determined. (S89).

After executing the processing of step S88 or S89, the main CPU 31 refers to the internal winning combination determination table for minor winning combination replay (see FIG. 20), and determines an internal winning combination based on the value of the small winning combination/replay data pointer. Acquire (S90).

In the process of step S90, the small combination/replay internal winning combination determination table is referred to, and 12 bytes indicating the internal winning combination corresponding to the value of the small combination/replay data pointer acquired in the process of step S88 or S89. is determined.

Next, the main CPU 31 stores the internal winning combination acquired in step S90 in the internal winning combination storing area (see FIG. 28) (S91). In the process of step S91, a 12-byte data value indicating the internal winning combination determined in the process of step S90 is stored in the internal winning combination storage areas (storage areas 1 to 3).

Next, the main CPU 31 determines whether or not the value of the carryover combination storing area (see FIG. 33) is 0 (S92). In the present embodiment, in this determination process, it is determined whether or not "MB" is carried over.

In step S92, when the main CPU 31 determines that the value of the carryover combination storing area is 0 (YES), the main CPU 31 refers to the bonus internal winning combination determination table (see FIG. 21) to determine the value of the bonus data pointer. (S93).

In the process of step S93, the bonus internal winning combination determination table is referenced, and a 12-byte data value indicating the internal winning combination corresponding to the value of the bonus data pointer acquired in the process of step S88 or S89 is determined. be.

Subsequently, the main CPU 31 stores the internal winning combination acquired in step S93 in the carryover combination storage area (see FIG. 33) (S94). In the process of step S94, when "MB" is acquired as the internal winning combination in step S93, bit 0 corresponding to "MB" in the carryover storage area is set to "1".

Next, the main CPU 31 determines whether or not the value of the carryover combination storing area (see FIG. 33) is 0 (S95). In this determination process, it is determined whether or not bit 0 corresponding to "MB" in the carryover storage area is set to "1" in step S94.

In step S95, when determining that the value of the carryover combination storing area is not 0 (NO), the main CPU 31 sets bit 2 corresponding to "RT1 gaming state" in the gaming state flag storing area (see FIG. 34) to " 1” (S96). By the processing of this step S96, the main game state becomes the RT1 game state.

If it is determined that the value of the carryover combination storing area is not 0 in step S92 (NO), if it is determined that the value of the carryover combination storing area is 0 in step S95 (YES), or after executing the process of step S96 , the main CPU 31 updates the internal winning combination storing area based on the internal winning combination stored in the carryover combination storing area (S97).

In the process of step S97, the 12-byte data value of the internal winning combination storing area (see FIG. 28) is updated based on the type of the internal winning combination stored in the carryover combination storing area (see FIG. 33). . After executing the process of step S97, the main CPU 31 terminates the internal lottery process.

<ART gaming state lottery processing>
FIG. 69 is a flow chart showing the ART gaming state lottery process executed in step S15 of the main control process shown in FIG.

First, the main CPU 31 determines whether or not the main game state is the MB game state (step S100). In this determination process, when the bit 0 corresponding to the "MB gaming state" in the gaming state flag storage area (see FIG. 34) is "1", it is determined that the main gaming state is the MB gaming state. 0", it is determined that the main game state is not the MB game state.

Here, when determining that the main game state is the MB game state (YES), the main CPU 31 terminates the ART game state lottery process. On the other hand, when determining that the main game state is not the MB game state (NO), the main CPU 31 determines whether the ART game state is the ART state (S101).

In this determination process, when the bit 6 corresponding to "ART state" in the game state flag storage area (see FIG. 34) is "1", it is determined that the ART game state is the ART state, and "0". , it is determined that the ART gaming state is not the ART state.

Here, when the main CPU 31 determines that the ART gaming state is the ART state (YES), the main CPU 31 executes processing during the ART state shown in FIG. 70 (S102). On the other hand, when determining that the ART gaming state is not the ART state (NO), the main CPU 31 determines whether the ART gaming state is the ART winning state (S103).

In this determination process, when the bit 4 corresponding to "ART winning state" in the gaming state flag storage area (see FIG. 34) is "1", it is determined that the ART gaming state is the ART winning state. 0”, it is determined that the ART gaming state is not the ART winning state.

Here, when the main CPU 31 determines that the ART gaming state is the ART winning state (YES), it executes the ART winning state processing shown in FIG. 71 (S104). On the other hand, when determining that the ART gaming state is not the ART winning state (NO), the main CPU 31 determines whether or not the ART gaming state is the ART start waiting state (S105).

In this determination process, when the bit 5 corresponding to "ART start waiting state" in the game state flag storage area (see FIG. 34) is "1", it is determined that the ART game state is the ART winning state. If it is "0", it is determined that the ART gaming state is not the ART winning state.

Here, when the main CPU 31 determines that the ART gaming state is the ART winning state (YES), the ART gaming state lottery process ends. On the other hand, when the main CPU 31 determines that the ART gaming state is not the ART winning state (NO), the main CPU 31 refers to the release lottery table (see FIG. 52) to determine the current release mode, set value, Based on the internal winning combination and the random value 2, it is determined whether or not the start lock release lottery has been won (S106), and based on the determined result, whether or not the start lock release lottery has been won (S107).

Here, when the main CPU 31 determines that the start lock release lottery is not won (NO), the main CPU 31 subtracts 1 from the number of unlocked games (S108). Subsequently, the main CPU 31 determines whether or not the number of unlocked games is 0 (S109), and when determining that the number of unlocked games is not 0 (NO), the main CPU 31 executes the ART gaming state lottery process. finish.

If it is determined in step S107 that the start lock release lottery has been won (YES), or if it is determined that the number of unlocked games is 0 in step S109 (YES), the main CPU 31 enters the ART gaming state. ART winning state is set as (S110).

The process of step S110 is a process of setting "1" to bit 4 corresponding to "ART winning state" in the game state flag storage area (see FIG. 34). The main CPU 31 that executes such processing constitutes game state transition means.

Subsequently, the main CPU 31 executes the ART winning state transition process shown in FIG. 72 (S111). This ART winning state transition processing includes processing for determining the transition destination mode, the number of games to be released next time, whether or not to perform a short freeze, the notification mode, and the like. After executing the ART winning state transition process, the main CPU 31 ends the ART gaming state lottery process.

<Processing during ART state>
FIG. 70 is a flow chart showing the ART-playing process executed in step S102 of the ART-game state lottery process shown in FIG.

First, the main CPU 31 refers to the long freeze reservation lottery table during ART shown in FIG. 56, and determines whether or not the long freeze reservation is won based on the internal winning combination and the random number value 2 (S121), Based on the determined result, it is determined whether or not the long freeze reservation has been won (S122).

Here, if it is determined that the long freeze reservation has not been won (NO), the main CPU 31 terminates the ART state process. On the other hand, when determining that the long freeze reservation has been won (YES), the main CPU 31 sets on the long freeze reservation flag stored in the main RAM 33 (S123).

Subsequently, the main CPU 31 refers to the mode transition lottery table (see FIGS. 37 to 45), and determines the transition destination mode based on the current release mode, the lottery opportunity, and the random value 3 (S124). , terminate the processing during the ART state.

<Process during ART winning state>
FIG. 71 is a flowchart showing the ART winning state process executed in step S104 of the ART gaming state lottery process shown in FIG.

First, the main CPU 31 determines whether or not the bonus reply 1 or 2 is internally won (S130).

Here, when it is determined that the bonus reply 1 or 2 has not been internally won (NO), the main CPU 31 ends the ART winning state processing. On the other hand, when it is determined that the bonus reply 1 or 2 has been internally won (YES), the main CPU 31 determines whether or not the announcement has been won based on the announcement mode stored in the main RAM 33. (S131), based on the determined result, it is determined whether or not the announcement has been won (S132).

That is, the main CPU 31 decides whether or not to execute an ART winning announcement based on the announcement probability in the determined announcement mode (see FIG. 72) every time the internal winning of the bonus reply 1 or 2 is made in the game in the ART winning state. to decide.

The main CPU 31 that executes such processing constitutes a winning announcement determining means. When it is decided to execute the ART winning announcement, the ART winning announcement is actually executed on the sub CPU 81 side.

Here, if it is determined that the notification has not been won (NO), the main CPU 31 ends the ART winning state process. On the other hand, if it is determined that the announcement has been won (YES), an ART start waiting state is set as the ART game state (S133).

In the process of step S133, the bit 4 corresponding to "ART winning state" in the gaming state flag storage area (see FIG. 34) is reset to "0", and the bit 5 corresponding to "ART start waiting state" is set to "1". ” is set.

Subsequently, the main CPU 31 turns on the notification flag stored in the main RAM 33 (S134), and ends the ART winning state processing.

<Processing when transitioning to ART winning state>
FIG. 72 is a flow chart showing the ART winning state transition processing executed in step S111 of the ART gaming state lottery processing shown in FIG.

First, the main CPU 31 refers to the mode transition lottery table (see FIGS. 37 to 45), and determines the transition destination mode based on the current release mode, set value, lottery opportunity, and random value 3 ( S140).

Next, the main CPU 31 refers to the unlocked game number lottery table (see FIGS. 46 to 51), and determines the next unlocked game number based on the current unlock mode, the set value, and the random value of 3. (S141).

Next, the main CPU 31 refers to the short freeze lottery table (see FIG. 53) when transitioning to the ART winning state, and determines whether or not the short freeze is won based on the release trigger and the random number value 3 (S142). ), and based on the determined result, it is determined whether or not the short freeze has been won (S143).

Here, when it is determined that the short freeze has been won (YES), the main CPU 31 sets the short freeze flag stored in the main RAM 33 to ON (S144).

If it is determined in step S143 that the short freeze has not been won (NO), or after turning on the short freeze flag, the main CPU 31 determines whether or not the long freeze reservation flag is on (S145). .

Here, if it is determined that the long freeze reservation flag is not on (NO), the main CPU 31 refers to the long freeze reservation lottery table (see FIG. 54) at transition to ART winning state, Based on this, it is determined whether or not the Long Freeze reservation has been won (S146), and based on the determined result, it is determined whether or not the Long Freeze reservation has been won (S147).

Here, when it is determined that the long freeze reservation has been won (YES), the main CPU 31 sets the long freeze reservation flag to ON (S148). Next, the main CPU 31 refers to the mode transition lottery table (see FIGS. 37 to 45), and determines the transition destination mode based on the current release mode, set value, lottery opportunity, and random value 3. (S149).

In step S145, if it is determined that the long freeze reservation flag is on (YES), in step S147, if it is determined that the long freeze reservation was not won (NO), or the long freeze reservation flag is set to on After that, the main CPU 31 refers to the announcement mode lottery table at the time of transition to the ART winning state, and determines the announcement mode based on the lottery opportunity and the random value 2 (S150).

In other words, the main CPU 31 determines one of the notification modes 1 to 3 having different notification probabilities that the execution of the ART winning notification is determined. At this time, the main CPU 31 determines the notification mode based on the notification mode distribution probability associated with each release condition in the notification mode lottery table at the time of transition to the ART winning state shown in FIG.

For example, when the number of games is canceled, notification mode 1 is distributed with a probability of 100%, and when watermelon is canceled, notification mode 1 or notification mode 2 is distributed with a probability of 50%. The main CPU 31 that executes such processing constitutes notification mode determination means.

<Reel stop initial setting process>
FIG. 73 is a flow chart showing the reel stop initialization process executed in step S16 of the main control process shown in FIG.

First, the main CPU 31 determines whether or not the main game state is the MB game state (S160). Here, when it is determined that the main game state is the MB game state (YES), the main CPU 31 sets 36 as the reel stop number (S161).

On the other hand, if it is determined that the main game state is not the MB game state (NO), the main CPU 31 sets the same data pointer as the small win/replay data pointer acquired in the process of step S89 of the internal lottery process shown in FIG. The value is set as the reel stop number (S162).

When the reel stop number is set in this manner, the main CPU 31 refers to the reel stop initial setting table (see FIG. 22) and obtains each piece of information based on the reel stop number (S163).

In the process of step S163, the main CPU 31 determines, for example, the number of the stop table used for the first to third stops and the information necessary to change the control in the control change process (that is, the reels 3L, 3C, and 3R are specified). information used for reselecting the stop table when stopped (or pressed) at a specific position when stopped in the order of ).

The stop table directly or indirectly stores information on the number of sliding symbols corresponding to the pressed position, and uses this information to the extent that it does not disadvantage the player and does not cause false winnings. , it is configured to stop at the stop position intended by the developer.

Next, the main CPU 31 stores the rotating identifier in each storage area of the pattern code storage area (see FIG. 30) (S164), stores 3 in the stop button non-actuated counter (S165), and initializes the reel stop. End the process.

<Freeze processing at the start of the game>
FIG. 74 is a flow chart showing the game start freeze process executed in step S18 of the main control process shown in FIG.

First, the main CPU 31 determines whether or not the short freeze flag is ON (S170). Here, when it is determined that the short freeze flag is ON (YES), the main CPU 31 sets 269 (approximately 0.3 seconds) to the effect freeze timer (S171).

On the other hand, when determining that the short freeze flag is not on (NO), the main CPU 31 determines whether or not the notification flag is on (S172). Here, if it is determined that the notification flag is not ON (NO), the main CPU 31 terminates the game start freeze processing. On the other hand, when determining that the notification flag is on (YES), the main CPU 31 determines whether or not the long freeze reservation flag is on (S173).

Here, when it is determined that the long freeze reservation flag is ON (YES), the main CPU 31 sets 10742 (about 12 seconds) to the effect freeze timer (S174). On the other hand, when determining that the long freeze reservation flag is not ON (NO), the main CPU 31 sets the effect freeze timer to 1791 (about 2 seconds) (S175).

Thus, when the value of the effect freeze timer is set in steps S171, S174 and S175, the main CPU 31 waits for the value of the effect freeze timer to become 0 (S176).

That is, when determining that the value of the effect freeze timer is not 0 (NO), the main CPU 31 executes the process of step S176. On the other hand, when determining that the value of the effect freeze timer has reached 0 (YES), the main CPU 31 clears the used flags to off (NO), and terminates the freeze processing at the start of the game.

<Priority attraction storage processing>
FIG. 75 is a flow chart showing the attraction priority storing process executed in step S22 of the main control process shown in FIG. 65 and step S234 of the reel stop control process shown in FIG.

First, the main CPU 31 stores the value of the stop button non-actuated counter in the main RAM 33 as the number of searches (S180). Next, the main CPU 31 executes search target reel determination processing for determining a reel to be searched. In this process, among the rotating reels, for example, one reel on the far left is determined as the reel to be searched.

Next, the main CPU 31 executes attraction priority table selection processing shown in FIG. 77 (S181). This attraction priority table selection process selects one attraction priority table number from the attraction priority table (see FIG. 24) (S182).

Next, the main CPU 31 sets the number of symbol checks stored in the main RAM 33 to 21 (the number of symbols on each reel), and sets the search symbol position to 0 (S183).

Next, the main CPU 31 executes the symbol code storage process shown in FIG. 76 (S184). In this symbol code storage process, the symbol code of the check symbol position data for checking the symbol position of the rotating reel is acquired.

Next, the main CPU 31 updates the display combination storing area (see FIG. 29) based on the acquired symbol code and the symbol code storing area (see FIG. 30) (S185). Next, the main CPU 31 executes attraction priority data acquisition processing (S186).

In this attraction priority order data acquisition process, for a combination in which the corresponding bit is 1 in the display combination storing area and the corresponding bit is 1 in the internal winning combination storing area (see FIG. 28), step S182 is performed. Attraction priority data is acquired by referring to the selected attraction priority table.

It should be noted that, in the drawing priority order data acquisition processing, "stop prohibited" (000H) is set for symbol positions that would result in an erroneous winning if stopped, and although internal winning is not performed, erroneous winning will not occur even if stopped. "Possible to stop" (001H) is set for the symbol position.

Next, the main CPU 31 stores the acquired attraction priority data in the attraction priority data storage area corresponding to the search target reel (S187). Next, the main CPU 31 subtracts 1 from the number of symbol checks and adds 1 to the searched symbol position (S188).

Next, the main CPU 31 determines whether or not the number of symbol checks is 0 (S189). Here, when determining that the number of symbol checks is not 0 (NO), the main CPU 31 executes the process of step S184.

On the other hand, when determining that the number of symbol checks is 0 (YES), the main CPU 31 determines whether or not the number of searches has been executed (S190). Here, if it is determined that searches have been performed for the number of searches (YES), the main CPU 31 terminates the attraction priority ranking storage process. On the other hand, when determining that searches have been performed for the number of searches (YES), the main CPU 31 executes the process of step S184.

<Design code storage processing>
FIG. 76 is a flow chart showing the symbol code storing process executed in step S184 of the attraction priority storing process shown in FIG.

First, the main CPU 31 sets effective line data (S200). In this embodiment, one valid line (middle-middle-middle) is set.

Next, the main CPU 31 sets check symbol position data for the search target reel based on the retrieved symbol position and the activated line data (S201). In this embodiment, for example, the symbol position in the middle row is set as check symbol position data for each reel.

Next, the main CPU 31 acquires the symbol code of the check symbol position data (S202), and terminates the symbol code storage process.

<Priority attraction table selection process>
FIG. 77 is a flow chart showing the attraction priority order table selection process executed in step S182 of the attraction priority order storage process shown in FIG.

First, the main CPU 31 determines whether or not attraction priority table selection data is set (S210). Here, if it is determined that the attraction priority table selection data is set (YES), the main CPU 31 refers to the pressing order storage area (see FIG. 32) and the operation stop button storage area (see FIG. 31). Then, the attraction priority table number corresponding to the attraction priority table selection data is set from the attraction priority table selection table (see FIG. 24) (S211), and the attraction priority table selection process is terminated.

On the other hand, when determining that the attraction priority order table selection data is not set (NO), the main CPU 31 sets the attraction priority order table corresponding to the attraction priority order table number (S212), and sets the attraction priority order table. End the selection process.

<Reel stop control processing>
FIG. 78 is a flow chart showing the reel stop control process executed in step S23 of the main control process shown in FIG.

First, the main CPU 31 determines whether or not a valid stop button has been pressed (S220). This process is a process of determining whether or not a signal has been output from the stop switch 7S. When the main CPU 31 determines that a valid stop button has not been pressed (NO), the main CPU 31 repeatedly executes the process of step S220.

On the other hand, when the main CPU 31 determines that a valid stop button has been pressed (YES), the pressing order storage area (see FIG. 32) and the operation stop button storage area (see FIG. 32) correspond to the pressed stop button. 31) are updated (S221).

Here, the main CPU 31 stores the type of operation stop button corresponding to each of the first stop operation, the second stop operation and the third stop operation in the pressing order storing area (see FIG. 32), and stores the pressing order storing area. , it is possible to determine the pressing order of the stop buttons 7L, 7C, and 7R.

Subsequently, the main CPU 31 subtracts 1 from the stop button non-actuated counter (S222), determines the reel to be searched from the activated stop button (S223), and stores the stop start position in the main RAM 33 based on the symbol counter ( S224). The stop start position is a symbol position corresponding to the symbol counter of the relevant reel when the stop operation is detected by the stop switch 7S.

Next, the main CPU 31 executes the number of sliding symbols determination process (S225). In this sliding symbol number determination process, the number of sliding symbols specified at the stop start position is determined based on the stop table selection data group selected based on the internal winning combination from the reel stop initial setting table (see FIG. 22). processing.

Next, the main CPU 31 executes the priority attraction control process shown in FIG. 79 (S226).
This priority attraction control process is performed so that the sliding piece stops at the symbol position corresponding to the higher priority attraction data within the range of the maximum number of sliding symbols. This is a process for correcting numbers.

Next, the main CPU 31 generates reel stop command data to be transmitted from the main control circuit 71 to the sub-control circuit 72, and stores the generated reel stop command data in the communication data storage area allocated to the main RAM 33 (S227). . This reel stop command data represents the type of reel to be stopped, the stop start position, the number of sliding symbols (or the planned stop position), and the like.

Next, the main CPU 31 determines the expected stop position based on the stop start position and the number of sliding symbols, and stores it in the main RAM 33 (S228). The planned stop position is a symbol position obtained by adding one of the predetermined numerical values "0" to "4" defined as the number of sliding symbols to the stop start position, and is the symbol position where the rotation of the reel stops. is.

Next, the main CPU 31 sets the planned stop position as the search symbol position (S229). Next, the main CPU 31 executes the pattern code storage process (see FIG. 76) (S230).

Next, the main CPU 31 updates the pattern code storage area from the pattern code acquired in the pattern code storage process (S231). Next, the main CPU 31 performs control change processing (S232). In this control change process, the reel stop information group is updated when the reel is at a specific stop position.

Next, the main CPU 31 determines whether or not the stop button non-actuated counter is 0 (S233). Here, if it is determined that the stop button inactive counter is not 0 (NO), the main CPU 31 executes the attraction priority storing process (see FIG. 75) (S234), and executes the process of step S220. On the other hand, when determining that the stop button non-actuated counter is 0 (YES), the main CPU 31 terminates the reel stop control process.

<Priority attraction control process>
FIG. 79 is a flow chart showing the priority pull-in control process executed in step S226 of the reel stop control process shown in FIG.

First, the main CPU 31 sets a pull-in priority data storage area corresponding to the operation stop button (S240). Next, the main CPU 31 acquires the stop start position stored in the main RAM 33 (S241).

Next, the main CPU 31 determines whether or not the MB is in operation (S242). In this determination process, when bit 0 of the game state flag storage area (see FIG. 34) is "1", it is determined that MB is in operation, and when it is "0", MB is in operation. Determine not inside.

Here, when determining that the MB is in operation (YES), the main CPU 31 determines whether or not the reel to be searched determined in step S223 of the reel stop control process shown in FIG. 78 is the left reel 3L. (S243).

When it is determined in step S242 that the MB is not in operation (NO), or when it is determined in step S243 that the reel to be searched is not the left reel 3L (NO), the main CPU 31 performs a step of the reel stop control process. A priority order table (see FIG. 25) corresponding to the data for determining the number of sliding symbols determined in S225 is set (S244).

For example, if the number of sliding symbols determined by the stop table (stop data table) is 4, the row (address) where the number of sliding symbols determination data of the priority order table is 4 is set. Next, the main CPU 31 sets the initial value of priority and the number of checks to 5 (S245). That is, it is decided to search for 0 to 4 frames five times.

In step S243, when it is determined that the reel to be searched is the left reel 3L (YES), the main CPU 31 sets the MB gaming state priority order table (see FIG. 26) according to the sliding piece number determination data. (S246). Subsequently, the main CPU 31 sets the initial value of priority to 3, and sets the number of checks to 2 (S247).

After executing the process of step S245 or S246, the main CPU 31 sets the number of sliding symbols as the number of sliding symbols (S248). Next, the main CPU 31 extracts a stop search position based on the stop start position and the priority order (S249).

Next, the main CPU 31 acquires attraction priority data for the stop search position (S250). Next, the main CPU 31 determines whether or not the attraction priority data obtained in the process of S250 is equal to or higher than the previously obtained attraction priority data (S251).

Here, if it is determined that the attraction priority data acquired in the process of S250 is equal to or higher than the attraction priority data acquired earlier (YES), the main CPU 31 updates the number of sliding symbols (S252).

In step S251, if it is determined that the attraction priority data acquired in the process of S250 is not equal to or greater than the attraction priority data acquired earlier (NO), or after executing the process of S251, the main CPU 31 determines the priority order and 1 is subtracted from each check count (S253).

Next, the main CPU 31 determines whether or not the number of checks is 0 (S254).
Here, when it is determined that the number of checks is 0 (YES), the main CPU 31 sets the number of sliding symbols (S255), and terminates the priority attraction control process. On the other hand, when determining that the number of checks is not 0 (NO), the main CPU 31 executes the process of S249.

<ART-related processing>
FIG. 80 is a flowchart showing ART-related processing executed in step S26 of the main control processing shown in FIG.

First, the main CPU 31 determines whether or not the main game state is the MB game state (S260). In this judgment process, if bit 0 of the gaming state flag storage area (see FIG. 34) is "1", it is judged that the main gaming state is the MB gaming state, and if it is "0", It is determined that the main game state is not the MB game state.

Here, when determining that the main game state is the MB game state (YES), the main CPU 31 terminates the ART-related processing. On the other hand, when determining that the main game state is not the MB game state (NO), the main CPU 31 determines whether the ART game state is the ART state (S261).

In this determination process, when the bit 6 of the game state flag storage area is "1", it is determined that the ART game state is the ART state, and when it is "0", the ART game state is the ART state. judged not to be.

Here, when determining that the ART gaming state is the ART state (YES), the main CPU 31 subtracts 1 from the number of ART games stored in the main RAM 33 (S262).

Next, the main CPU 31 determines whether or not the number of ART games is 0 (S263). Here, when determining that the number of ART games is not 0 (NO), the main CPU 31 ends the ART-related processing.

On the other hand, if it is determined that the number of ART games is 0 (YES), the main CPU 31 determines when the ART state transitioned due to the winning of BB reply 1 or BB reply 2 ends (hereinafter simply referred to as "at the end of BB"). is described) (S264).

Here, if it is determined that it is time to end the BB (YES), the main CPU 31 sets the BB end flag stored in the main RAM 33 to "1" (S265), and ends the ART-related processing.

On the other hand, if the main CPU 31 determines that it is not the end of the ART state shifted by the winning of the BB descriptor 1 or BB descriptor 2, that is, the ART state shifted by the winning of the RB descriptor (NO), the main CPU 31 stores it in the main RAM 33. The RB end flag is set to "1" (S266), and the ART-related processing is ended.

When it is determined in step S261 that the ART gaming state is not the ART state (NO), the main CPU 31 determines whether or not the ART gaming state is the ART start waiting state (S267).

In this judgment process, if bit 5 of the game state flag storage area (see FIG. 34) is "1", it is judged that the ART game state is waiting for ART start, and if it is "0", , it is determined that the ART gaming state is not the ART start waiting state.

Here, when determining that the ART gaming state is not the ART start waiting state (NO), the main CPU 31 terminates the ART related processing. On the other hand, if it is determined that the ART gaming state is the state of waiting for the ART start (YES), the main CPU 31, when winning BB reply 1 or BB reply 2 (hereinafter simply referred to as "when winning BB reply"), It is determined whether or not there is (S268).

When it is determined that it is time to win the BB reply (YES), the main CPU 31 sets the BB start flag stored in the main RAM 33 to "1" (S269), and sets 70 games, for example, as the number of ART games. (S270), ART-related processing is terminated.

On the other hand, if it is determined that it is not at the time of BB reply winning (NO), the main CPU 31 determines whether or not it is at the time of winning RB reply (hereinafter simply referred to as "at the time of winning RB reply") (S271). . Here, if it is determined that it is the RB reply winning time (YES), the main CPU 31 sets the RB start flag stored in the main RAM 33 to "1" (S272), and the number of ART games is, for example, 20 games. is set (S273), and the ART-related processing is terminated.

Thus, the main CPU 31 that executes the ART-related processing shown in FIG. 80 constitutes lock determining means.

<Lock processing at the end of the game>
FIG. 81 is a flow chart showing the lock process at the end of the game executed in step S27 of the main control process shown in FIG.

First, the main CPU 31 determines whether or not the BB start flag is ON (S280). Here, when determining that the BB start flag is ON, the main CPU 31 sets 4476 (approximately 5 seconds) to the effect lock timer (S281) and turns on the external signal 1 (S282). That is, the main CPU 31 turns on (first state) the external signal 1 that is transmitted to the outside of the gaming machine, on the condition that the start lock is performed.

On the other hand, when determining that the BB start flag is not on, the main CPU 31 determines whether or not the RB start flag is on (S283). Here, when determining that the RB start flag is on, the main CPU 31 sets the effect lock timer to 1 (S284) and turns on the external signal 2 (S285). That is, the main CPU 31 turns on (first state) the external signal 2 that is transmitted to the outside of the gaming machine, on the condition that the start lock is performed.

After executing the processing of step S282 or S285, the main CPU 31 sets the ART state as the ART gaming state (S286). In the process of step S286, bit 5 corresponding to "ART start waiting state" in the gaming state flag storage area (see FIG. 34) is reset to "0", and bit 6 corresponding to "ART state" is set to "1". is set to

When determining in step S283 that the RB start flag is not on, the main CPU 31 determines whether or not the BB end flag is on (S287). Here, when determining that the BB end flag is ON, the main CPU 31 sets 3581 (approximately 4 seconds) to the effect lock timer (S288) and turns off the external signal 1 (S289).
That is, the main CPU 31 turns off the external signal 1 that was turned on in step S282 (second state) on the condition that the end lock is performed.

On the other hand, when determining that the BB end flag is not on, the main CPU 31 determines whether or not the RB end flag is on (S290). Here, when determining that the RB end flag is on, the main CPU 31 sets the effect lock timer to 1 (S284) and turns off the external signal 2 (S292). That is, the main CPU 31 turns off the external signal 2 that was turned on in step S285 (second state) on the condition that the end lock is performed.

After executing the process of step S289 or S292, the main CPU 31 sets the normal game state as the ART game state (S293). In the process of step S293, bit 6 corresponding to "ART state" in the game state flag storage area (see FIG. 34) is reset to "0".

After executing the process of step S286 or S293, the main CPU 31 waits until the value of the effect lock timer becomes 0 (S294). That is, when determining that the value of the effect freeze timer is not 0 (NO), the main CPU 31 executes the process of step S294.

On the other hand, when determining that the value of the effect freeze timer has reached 0 (YES), the main CPU 31 clears each used flag to off (NO), and terminates the lock processing at the end of the game.

Thus, the main CPU 31 that executes the ART-related processing shown in FIG. 80 and the lock processing at the end of the game shown in FIG. 81 constitutes external signal control means, start lock execution means, and end lock execution means.

In the present embodiment, the main CPU 31 turns on the external signals 1 and 2 respectively when the BB start flag or RB start flag is on, and when the BB end flag or RB end flag is on, the external signal It has been explained that 1 and 2 are turned off.

On the other hand, the main CPU 31 turns off the external signals 1 and 2 when the BB start flag or RB start flag is on, and turns off the external signals 1 and 2 when the BB end flag or RB end flag is on. Each of them may be turned on. In this case, the state in which the external signals 1 and 2 are on corresponds to the first state, and the state in which they are off corresponds to the second state.

<Bonus end check processing>
FIG. 82 is a flow chart showing bonus end check processing executed in step S29 of the main control processing shown in FIG.

First, the main CPU 31 determines whether MB is in operation (S300). In this process, when the bit 0 of the game state flag storage area is "1", it is determined that the MB is in operation, and when the bit 0 of the game state flag storage area is "0", the MB is in operation. judged not to be inside.

Here, when determining that the MB is in operation (YES), the main CPU 31 terminates the bonus end check process. On the other hand, when determining that the MB is in operation (YES), the main CPU 31 executes CB end processing (S301). In this CB termination process, bit 1 of the gaming state flag storage area is reset to "0".

Subsequently, the main CPU 31 updates the bonus ending number counter indicating the remaining payout number (S302), and determines whether or not the value of the bonus ending number counter is less than 0 (S303).

Here, when determining that the value of the bonus end number counter is not less than 0 (NO), the main CPU 31 ends the bonus end check process. On the other hand, when determining that the value of the bonus end number counter is less than 0, the main CPU 31 performs MB end processing (S304). In the MB end process, bit 0 of the gaming state flag storage area is reset to "0".

Subsequently, the main CPU 31 generates bonus end command data to be transmitted from the main control circuit 71 to the sub control circuit 72, and stores the generated bonus end command data in the communication data storage area allocated to the main RAM 33 (S227). , ends the bonus end check process. Here, the bonus end command data indicates, for example, that the bonus has ended.

<Bonus activation check process>
FIG. 83 is a flow chart showing bonus activation check processing executed in step S30 of the main control processing shown in FIG.

First, the main CPU 31 determines whether MB is in operation (S310). In this process, when the bit 0 of the gaming state flag storage area is "1", it is determined that the MB is in operation, and when the bit 0 of the gaming state flag storage area is "0", the MB judged to be inactive.

Here, when determining that the MB is in operation (YES), the main CPU 31 executes CB operation processing (S311), and ends the bonus operation check processing. In the CB activation process, bit 1 of the gaming state flag storage area is set to "1".

On the other hand, when determining that the MB is not in operation (NO), the main CPU 31 determines whether or not the MB has won (S312). Here, when determining that MB has won a prize, the main CPU 31 executes MB operation processing (S313).

In the MB operation process, bit 0 of the game state flag storage area is set to "1", a bonus end number counter is set to 30, for example, and a bit of the game state flag storage area is set to "1".

Next, the main CPU 31 clears the value of the carryover combination storage area (S314), generates bonus start command data to be transmitted from the main control circuit 71 to the sub control circuit 72, and stores the generated bonus start command data in the main RAM 33. The data is stored in the allocated communication data storage area (S315), and the bonus activation check process is terminated.

In step S312, when it is determined that the MB did not win, the main CPU 31 performs replays (“BB reply 1”, “BB reply 2”, “RB reply”, “normal reply” and “special replay 1” to "Special replay 11") is displayed (S316).

Here, when determining that the replay was not displayed (NO), the main CPU 31 terminates the bonus activation check process. On the other hand, when determining that the replay has been displayed (YES), the main CPU 31 makes an automatic insertion request to copy the value of the insertion number counter to the automatic insertion number counter (S317), and ends the bonus operation check process.

<Interrupt processing under the control of the main CPU>
FIG. 84 is a flow chart showing interrupt processing under the control of the main CPU 31. FIG. This process is performed every 1.1172 milliseconds.

First, the main CPU 31 saves the register (S320). Next, the main CPU 31 executes input port check processing shown in FIG. 85 (S321). In this process, the main CPU 31 confirms whether or not there is a signal to be sent to the sub-control circuit 72 .

For example, the main CPU 31 stores in the communication data storage area of the main RAM 33 input state command data representing on-edge and off-edge information of various switches including the on-edge and off-edge of the start switch 6S and the stop switch 7S.

Next, the main CPU 31 executes timer update processing (S322). Next, the main CPU 31 executes communication data transmission processing shown in FIG. 86 (S323). In this process, the command data stored in the communication data storage area of the main RAM 33 is sent to the sub control circuit 72 .

Next, the main CPU 31 executes reel control processing for controlling the rotation of the reels 3L, 3C, and 3R (S324). More specifically, the main CPU 31 starts rotating the reels 3L, 3C, and 3R in response to a request to start rotating the reels 3L, 3C, and 3R, that is, a start operation, and rotates the reels at a constant speed. Control is performed so that 3L, 3C, and 3R rotate. Further, the main CPU 31 performs control such that the rotation of the reels 3L, 3C, and 3R corresponding to the stop operation is stopped according to the stop operation.

Next, the main CPU 31 executes lamp/7SEG drive processing (S325). For example, the main CPU 31 displays the number of credited medals, the number of payouts, etc. on various display units. Next, the main CPU 31 restores the register (S326), and terminates the periodically generated interrupt processing.

<Input port check processing>
FIG. 85 is a flow chart showing the input port check process executed in step S321 of the interrupt process under the control of the main CPU 31. FIG.

First, the main CPU 31 checks the state of each input port (S330). Next, the main CPU 31 stores the previous interrupt, that is, the state of the input port one interrupt before, in the main RAM 33 (S331), and stores the current state of the input port in the main RAM 33 (S332).

In this way, by comparing the state of the input port before one interrupt with the state of the current input port, the main CPU 31 can confirm the state of both input ports. , and it is checked whether the state of the input port has changed, for example, whether the bet button 11 has been pressed.

Next, the main CPU 31 stores the on-edge state in the main RAM 33 (S333). In the present embodiment, "on-edge" refers to the state in which the button is pressed, and "off-edge" refers to the state in which the button is released.

Next, the main CPU 31 generates input state command data to be transmitted from the main control circuit 71 to the sub control circuit 72, and stores the generated input state command data in the communication data storage area allocated to the main RAM 33 (S334). , ends the input port check process.

<Communication data transmission processing>
FIG. 86 is a flow chart showing communication data transmission processing executed in step S323 of the interrupt processing under the control of the main CPU 31. FIG.

First, the main CPU 31 subtracts 1 from the communication data transmission timer (S340). Next, the main CPU 31 determines whether or not the communication data transmission timer is 0 (S341).

Here, when determining that the communication data transmission timer is not 0 (NO), the main CPU 31 terminates the communication data transmission process. On the other hand, when determining that the communication data transmission timer is 0 (YES), the main CPU 31 determines whether or not there is unsent data in the communication data storage area (S342).

Here, if it is determined that there is no unsent data in the communication data storage area (NO), the main CPU 31 generates no-operation command data indicating that there is no data to be transmitted, and generates no-operation command data. is stored in the communication data storage area allocated to the main RAM 33 (S343).

When it is determined in step S342 that there is unsent data in the communication data storage area, or after executing the processing of step S343, the main CPU 31 sets the communication data transmission timer to an initial value of 14, for example (S344).

Next, the main CPU 31 transmits the communication data stored in the communication data storage area to the sub control circuit 72 (S345). Next, the main CPU 31 determines whether or not transmission of communication data has been completed (S346).

Here, when determining that the transmission of the communication data has not been completed (NO), the main CPU 31 executes the process of step S345. On the other hand, if it is determined that the transmission of the communication data has been completed (YES), the main CPU 31 updates the communication data storage area so as to clear it (S347), and terminates the communication data transmission process.

In this way, the main CPU 31 that outputs the communication data, which is information about the progress of the game stored in the communication data storage area, to the sub-control circuit 72 constitutes information output means in this embodiment.

[Secondary control processing]
The sub CPU 81 of the sub control circuit 72 executes various processes according to the flow charts shown in FIGS. 87-102.

<Power-on processing>
FIG. 87 is a flowchart showing power-on processing of the sub CPU 81 when power is turned on.

First, the sub CPU 81 executes initialization processing (S350). In this process, the sub CPU 81 performs an error check on the sub RAM 83 and the like and initializes the OS. The OS includes a mother task shown in FIG. 88, which is a task group of a main control board communication task, an LED output control task, and a sound control task, which are task groups of timer interrupt synchronization.

Next, the sub CPU 81 activates the mother task (S351) and terminates the power-on process.

<Mother task>
FIG. 88 is a flow chart showing the mother task activated in step S351 of the power-on process shown in FIG.

In the mother task, first, the sub CPU 81 activates the main board communication task (S360).

Next, the sub CPU 81 activates the LED output control task shown in FIG. 89 (S361). The LED output control task waits for the sub CPU 81 to receive a timer interrupt event message that is activated every 2 milliseconds to the sub CPU 81, and in response to receiving this timer interrupt event message, various LED , and the processing for controlling the dot display device 100. FIG.

Next, the sub CPU 81 activates the sound control task shown in FIG. 92 (S362).
In the sound control task, the sub CPU 81 controls the sound output state from the speakers 9L and 9R.

<LED output control task>
FIG. 89 is a flow chart showing the LED output control task activated in step S361 of the mother task shown in FIG.

First, the sub CPU 81 executes initialization processing of the LED output related data (S370).

Next, the sub CPU 81 executes the LED output data analysis process shown in FIG. 90 (S371). In this process, the sub CPU 81 determines LED effect data to be executed from each piece of control information.

Next, the sub CPU 81 executes the LED output control execution process shown in FIG. 91 (S372), and executes the process of step S371. In this process, the sub CPU 81 executes the LED effect determined by the LED output data analysis process based on the result of the LED output data analysis process executed in step S371.

<LED output data analysis processing>
FIG. 90 is a flow chart showing the LED output data analysis process executed in step S371 of the LED output control task shown in FIG.

First, the sub CPU 81 determines whether or not effect registration information is set (S530). In this process, the sub CPU 81 determines that the effect registration information set based on the effect data in the LED data determination process (see step S411) of the command analysis process (see FIG. 98) is set in a predetermined area of the sub RAM 83. determine whether or not

In the process of step S530, when it is determined that the effect registration information is set (YES), the sub CPU 81 acquires LED effect data (S531). In this process, the sub CPU 81 acquires the LED effect data by referring to the effect number corresponding to the effect registration information and the LED/sound output list table (see FIG. 64).

Next, the sub CPU 81 sets the LED effect data to the request registration information (S532), and terminates the LED output data analysis process. In this process, the sub CPU 81 sets the LED effect data acquired in step S531 to the request registration information.

In the process of step S530, when it is determined that the effect registration information is not set (NO), the sub CPU 81 determines whether or not the LED effect is being executed (S533). In this process, the sub CPU 81 refers to the LED control state information, which is information about the current execution status of the LED effect data, and determines whether or not the LED effect is being executed. To confirm whether or not the registered LED effect data are executed without omission.

In the process of step S533, when it is determined that the LED effect is being executed (YES), the LED output data analysis process is terminated. On the other hand, when it is determined in the process of step S533 that the LED effect is not being executed (NO), the sub CPU 81 acquires sound reproduction information (S534). In this process, the sub CPU 81 acquires sound reproduction information and confirms the current execution status of the sound effect.

Next, the sub CPU 81 determines whether or not there is sound data being reproduced (S535). In this process, the sub CPU 81 determines from the sound reproduction information obtained in step S534 whether a predetermined reproduction time set for the sound data being executed by the DSP 84 has elapsed since the DSP 84 started executing the sound data. By confirming whether or not, it is determined whether or not the sound effect is currently being executed.

In the process of step S535, if it is determined that there is no sound data being reproduced (NO), the sub CPU 81 terminates the LED output data analysis process. On the other hand, if it is determined in the process of step S535 that there is sound data being reproduced (YES), the sub CPU 81 acquires LED effect data from the LED/sound output list table (S536). In this process, the sub CPU 81 refers to the command number corresponding to the sound data being reproduced and the LED/sound output list table to acquire the LED effect data.

Next, the sub CPU 81 determines whether or not the LED effect data has been obtained (S537). In this process, the sub CPU 81 determines whether or not the LED effect data could be acquired in the process of step S536.

In the process of step S537, if the LED effect data could not be obtained (NO), the sub CPU 81 terminates the LED output data analysis process. On the other hand, in the process of step S537, when the LED effect data can be obtained (YES), the sub CPU 81 sets the LED effect data to the request registration information (S538), and ends the LED output data analysis process.

In this way, when the DSP 84 is executing the sound data, the LED effect data associated with the sound data being executed by the DSP 84 is transmitted to the sub CPU 81 and each part of the pachi-slot machine 1 that executes the LED effect data ( The sub CPU 81 that determines whether the dot display device 100, the reel effect display device 103, the side effect display device 104, and the light emitting unit 330) is executing constitutes the effect information determination means in this embodiment.

Further, as shown in the processing of steps S533 to S538, the sub CPU 81 causes the LED effect data associated with the sound data being executed by the DSP 84 to be executed by each part of the pachi-slot machine 1 that executes the LED effect data. By setting the LED effect data associated with the sound data to the request registration information when it is determined that the LED effect data is not registered, the LED effect data is transferred from the sub ROM 82 to the sub CPU 81 .

With this configuration, the pachi-slot machine 1 according to the present embodiment has the LED effect data associated with the sound data, the sound data being executed, and the LED effect data associated with the sound data being executed. is not executed, the associated LED effect data is transferred from the sub ROM 82 to the sub CPU 81 and executed. An increase in design man-hours can be prevented.

Further, in the pachi-slot machine 1 according to the present embodiment, if the LED effect data associated with the sound data being executed is not being executed during the period from the start of execution of the sound data until the predetermined reproduction time elapses. , Since the sub CPU 81 manages the execution of sound data, it is not necessary to determine whether the sound data is being executed each time, the number of times control processing is executed can be reduced, and the occurrence of bugs can be suppressed. be able to.

<LED output control execution processing>
FIG. 91 is a flowchart showing LED output control execution processing executed in step S372 of the LED output control task shown in FIG.

First, the sub CPU 81 executes a request registration information acquisition process for an LED effect (S540). In this process, the sub CPU 81 acquires the current set status of the request registration information of the LED effect data set in step S532 or step S538 of the LED output data analysis process (see FIG. 90).

Next, the sub CPU 81 determines whether or not request registration information is set (S541). In this process, the sub CPU 81 determines whether or not the request registration information is set from the request registration information acquired in the process of step S540.

In the process of step S541, if it is determined that the request registration information is set (YES), the sub CPU 81 executes the LED output control process based on the request registration information (S542). In this process, the sub CPU 81 executes an output control process for controlling the LED of the target part for executing the LED effect data associated with each LED effect data based on the request registration information.

In the process of step S542, when the sub CPU 81 acquires new request registration information during execution of the LED effect data, that is, transfers the new request registration information, the sub CPU 81 transfers the LED effect data based on the newly transferred request registration information. configured to run.

With this configuration, the pachi-slot machine 1 according to the present embodiment preferentially executes the new LED effect data when new LED effect data is transferred even while the LED effect data is being executed. , when the sound data is executed, the LED effect data associated with the sound data can be surely executed, and whether or not the LED effect data associated with the sound data is executed when the sound data is executed at the time of design. Therefore, it is possible to easily check whether or not the design is correct, thereby reducing design man-hours and suppressing the occurrence of bugs.

In the processing of step S541, if it is determined that the request registration information is not set (NO) or after executing the processing of step S542, the sub CPU 81 updates the LED control state information (S543), and executes LED output control. End the process. In this process, the sub CPU 81 determines whether or not the current LED effect is being executed, if the LED effect is being executed, the LED effect data being executed, and the time elapsed since the start of the LED effect being executed. A process of reflecting such information in the LED control state information is executed.

<Sound control task>
FIG. 92 is a flow chart showing the sound control task activated in step S362 of the mother task shown in FIG.

First, the sub CPU 81 executes the sound-related data initialization process shown in FIG. 93 (S380). In this process, the sub CPU 81 executes initial setting process of each sound data related to the sound output state from the speakers 9L and 9R.

Next, the sub CPU 81 executes sound data analysis processing shown in FIG. 94 (S381). In this process, the sub CPU 81 determines sound data to be executed from each control information.

Next, the sub CPU 81 performs sound effect execution processing shown in FIG. 95 (S382), and executes the processing of step S381. In this process, the sub CPU 81 executes the sound effect determined by the sound data analysis process based on the result of the sound data analysis process executed in step S381.

<Initialization of sound-related data>
FIG. 93 is a flow chart showing initialization processing of sound-related data executed in step S380 of the sound control task shown in FIG.

First, the sub CPU 81 transfers the sound data of the sound type "file" in the sound list table (see FIGS. 61 and 62) to the DSP 84 (S490). In this process, the sub CPU 81 refers to the sound list table, transfers the sound data of the sound type “file” set to type “1” among the sound data to the DSP 84 and stores it in the audio RAM 85 .

Next, the sub CPU 81 generates a management table for registering the sound data of the sound type "file" and the sound data of the sound type "stream" (S491), and ends the sound related data initialization process. In this process, the sub CPU 81 refers to the sound list table and creates, in a predetermined area of the sub RAM 83, a management table for classifying and registering each sound data by sound type.

In this way, when the sub-control circuit 72 is activated, the audio RAM 85 that stores the sound data set to type "1" out of the plurality of sound data stored in the sub-ROM 82 is used for the specific effect in the present embodiment. It constitutes information storage means.

In addition, in the process of step S490, the sub CPU 81 transfers sound data set to type "1" to the DSP 84 more often than sound data set to type "2". It is configured to be stored in the audio RAM 85 when the circuit 72 is activated.

With this configuration, the pachi-slot machine 1 according to the present embodiment outputs the sound data set to type "1", which is frequently executed by the DSP 84 and requires high responsiveness, when the sub-control circuit 72 is activated. When sound data stored in the audio RAM 85 from the sub-ROM 82 and set to type "1" is executed, it is transferred from the audio RAM 85 to the DSP 84 and executed. It is possible to prevent it from occurring and to execute an effect that satisfies the required responsiveness.

<Sound data analysis processing>
FIG. 94 is a flow chart showing sound data analysis processing executed in step S381 of the sound control task shown in FIG.

First, the sub CPU 81 determines whether or not effect registration information is set (S500). In this process, the sub CPU 81 causes the effect registration information set based on the effect data in the sound data determination process (see step S412) of the command analysis process (see FIG. 93) to be set in a predetermined area of the sub RAM 83. determine whether or not

In the process of step S500, if it is determined that the effect registration information is not set (NO), the sub CPU 81 terminates the sound data analysis process. On the other hand, if it is determined in the process of step S500 that the effect registration information has been set (YES), the sub CPU 81 determines whether or not the set effect registration information is sequence reproduction information ( S501).

In the process of step S501, when it is determined that the effect registration information is the sequence reproduction information (YES), the sub CPU 81 executes the sequence reproduction request request process (S502) and ends the sound data analysis process. In the processing of steps S501 and S502, the sub CPU 81 refers to the sound sequence table (see FIG. 63) when the effect registration information is sequence reproduction information set by satisfying a predetermined condition. , sets the request registration information requesting the DSP 84 to execute the sequence number corresponding to the sequence playback information.

Here, the request request means that the sub CPU 81 makes a request registration request to the driver for requesting the DSP 84 to transfer and execute each data. , the control processing to the DSP 84 is executed.

In the processing of step S501, when it is determined that the effect registration information is not sequence reproduction registration (NO), the sub CPU 81 acquires sound reproduction information (S503).
In this process, the sub CPU 81 acquires sound reproduction information, which is information composed of the content of the sound effect being executed, that is, the sound data being executed, and the time elapsed from the start of the sound effect being executed. do.

Next, the sub CPU 81 determines whether or not there is a sound being reproduced or a sound reproduction request has already been made (S504). In this process, the sub CPU 81 determines whether the sound effect has already been executed by the DSP 84 based on the sound reproduction information obtained in step S503, or whether there is a sound reproduction request request that has not yet been executed.

In the processing of step S504, if it is determined that there is a request for the sound being reproduced or there is already a sound reproduction request (YES), the sub CPU 81 executes the next sound reproduction request request processing based on the effect registration information (S505). End the data analysis process. In this process, the sub CPU 81, after executing the currently playing sound or the already set sound reproduction request request, performs A next sound reproduction request is issued to the DSP 84 so as to execute the sound data associated with the determined command number.

In the process of step S504, if it is determined that there is no sound being reproduced or no sound reproduction request has already been made (NO), the sub CPU 81 executes sound reproduction request processing based on the effect registration information (S506), End analysis processing.
In this process, the sub CPU 81 instructs the DSP 84 to execute the sound data associated with the command number determined from the effect number confirmed in step S500 and the sound list table (see FIGS. 61 and 62). Execute a playback request request.

<Sound production execution processing>
FIG. 95 is a flow chart showing sound effect execution processing executed in step S382 of the sound control task shown in FIG.

First, the sub CPU 81 executes processing for acquiring sound request registration information (S510). In this process, the sub CPU 81 is set in a predetermined area of the sub RAM 83 when a sequence reproduction request or sound reproduction request is executed in step S502 or step S506 of the sound data analysis process (see FIG. 94). Get the current set status of the request registration information.

Next, the sub CPU 81 determines whether or not request registration information is set (S511). In this process, the sub CPU 81 determines whether the request registration information is set from the request registration information acquired in the process of step S510.

In the process of step S511, if it is determined that the request registration information is not set (NO), the sub CPU 81 updates the sound reproduction information (S512) and ends the sound effect execution process. In this process, the sub CPU 81 determines the presence or absence of the current sound effect by the DSP 84, the sound data being executed if the sound effect is being executed, and the time elapsed from the start of the sound effect being executed. A process for reflecting the information in the sound reproduction information is executed.

In the process of step S511, if it is determined that the request registration information is set (YES), the sub CPU 81 determines whether the set request registration information is a sequence reproduction request (S513). In this process, if it is determined that the sequence reproduction information is set, the sub CPU 81 executes the sequence reproduction request process (S514) and ends the sound effect execution process.

In the processing of steps S513 and S514, the sub CPU 81 reads the sound sequence table (see FIG. 63) because the set request registration information is a sequence reproduction request set by satisfying a predetermined condition. By referring to it, the sequence number corresponding to the sequence reproduction information for which the sequence reproduction request was executed is determined, and the DSP 84 is requested to continuously execute a plurality of sound data associated with the sequence number.

In the process of step S513, if it is determined that the set request registration information is not a sequence reproduction request (NO), the sub CPU 81 acquires the command number corresponding to the sound reproduction request set in the request registration information. (S515). In this process, the sub CPU 81 refers to the effect number corresponding to the sound reproduction request and the sound list table (see FIGS. 61 and 62) to acquire the command number corresponding to the effect number.

Next, the sub CPU 81 acquires the sound type from the command number (S516). In this process, the sub CPU 81 refers to the sound list table (see FIGS. 61 and 62) and obtains the value set for the type of the command number obtained in step S515.

Next, the sub CPU 81 determines whether or not the sound type is "file" (S517). In this process, the sub CPU 81 determines whether or not the sound type of the command number acquired in the process of step S516 is "file".

If it is determined in step S517 that the sound type is "file" (YES), the sub CPU 81 generates access reproduction request information for sound data of the sound type "file" (S518).

In the process of step S518, the sub CPU 81 extracts the command number obtained in step S515 and the sound data of the sound type "file" extracted from the management table generated in step S491 of the sound-related data initialization process (see FIG. 93). and the access information of the sound data corresponding to the sound reproduction request. Here, the access reproduction request information is information used when requesting the DSP 84 to execute sound data.

The access reproduction request information generated in the process of step S518 is configured to cause the DSP 84 to execute the sound data stored in the audio RAM 85. FIG.

That is, in the present embodiment, sub CPU 81 sends sound data set to type "1" stored in audio RAM 85 to DSP 84 when causing DSP 84 to execute sound data set to type "1". configured to forward.

In the process of step S517, if it is determined that the sound type is not "file" (NO), the sub CPU 81 generates access reproduction request information for sound data of the sound type "stream" (S519). In this process, the sub CPU 81, from the command number acquired in step S515 and the access information of the sound data of the sound type "stream" extracted from the management table generated in step S491 of the sound-related data initialization process, Generate access reproduction request information of sound data corresponding to the sound reproduction request.

After executing the process of step S518 or step S519, the sub CPU 81 executes a sound data reproduction request to the DSP 84 based on the access reproduction request information (S520), and ends the sound effect execution process. In this process, the sub CPU 81 requests the DSP 84 to reproduce the sound data corresponding to the sound reproduction request based on the access reproduction request information generated in each process of steps S518 and S519.

As shown in FIGS. 94 and 95, sound data request registration information is set from the performance number, and the DSP 84 is requested to reproduce the sound data. The sub CPU 81 that performs this constitutes effect information transfer means in the present embodiment.

Further, as shown in FIGS. 93 to 95, the pachi-slot machine 1 according to the present embodiment outputs sound data set to type "1" when the sub-control circuit 72 is activated in the sound-related data initialization process. By changing the transfer source of the sound data according to the type of sound data stored in the audio RAM 85 from the sub-ROM 82 and executed by the DSP 84, it is possible to prevent the transfer of the sound data from causing a problem in responsiveness. It is possible to execute an effect that satisfies the responsiveness.

As shown in FIGS. 94 and 95, as sound data to be executed by the DSP 84, a sound sequence is transferred to the DSP 84 when a predetermined condition is satisfied, and a plurality of sound data constituting the transferred sound sequence is transferred to the DSP 84. The sub CPU 81, which causes the sub CPU 81 to be executed continuously, constitutes effect information group transfer means in the present embodiment.

With this configuration, the pachi-slot machine 1 according to the present embodiment stores a sound sequence in the sound sequence table of the sub ROM 82 in advance when the DSP 84 wants to continuously execute a plurality of sound data. By selecting this option, multiple pieces of sound data can be executed in succession, so even when multiple pieces of sound data are executed in succession, it is possible to prevent responsiveness problems caused by transferring sound data. It is possible to execute an effect that satisfies the required responsiveness.

Therefore, in the pachi-slot machine 1 according to the present embodiment, for example, when confirming the behavior of the pachi-slot machine 1 when playing a plurality of arbitrary sound data in succession, it is set that a predetermined condition has been established. By creating a sound sequence composed of a plurality of arbitrary sound data, the behavior of the pachi-slot machine 1 can be confirmed, and the sound data can be easily confirmed and corrected.

<Main board communication task>
FIG. 96 is a flow chart showing the main board communication task activated in step S360 of the mother task shown in FIG.

First, the sub CPU 81 initializes the communication message queue (S390) and checks the received command (S391).

Next, the sub CPU 81 creates game information from the received command, and stores the created game information in the sub RAM 83 (S392). Next, the sub CPU 81 executes the command analysis process shown in FIG. 98 (S393), and executes the process of step S391.

<Receive command check processing>
FIG. 97 is a flow chart showing the received command check process executed in step S391 of the main board task shown in FIG.

First, the sub CPU 81 checks the order of the command received this time and the command received last time (S400), and determines whether or not the command order is normal (S401). In this process, for example, when the command received this time is a "start command" and the command received immediately before is a "medal insertion command", the sub CPU 81 determines that the order is normal, and If a command other than the "input command" is received immediately before the current command is received, it is determined that the order is abnormal. When the received command is an input state command, the sub CPU 81 does not determine the command order.

In the process of step S401, if it is determined that the order of the commands is normal (YES), the sub CPU 81 terminates the received command check process. On the other hand, if it is determined in the process of step S401 that the order of the commands is abnormal (NO), the sub CPU 81 sets a sequence error (S402) and terminates the received command check process. Here, a sequence error is an error that occurs when commands are received in an order that cannot occur in a normal game, and can be canceled by resetting the door key and changing the settings.

Thus, in this embodiment, the sub CPU 81 constitutes reception order determination means.

<Command analysis processing>
FIG. 98 is a flow chart showing command analysis processing executed in step S393 of the main board communication task shown in FIG.

First, the sub CPU 81 executes effect content determination processing shown in FIG. 99 (S410). In this process, the sub CPU 81 executes effect content determination processing for determining effect data based on command data included in the information data output from the main CPU 31 .

Next, the sub CPU 81 executes LED effect data determination processing (S411). In this process, the sub CPU 81 sets the effect registration information related to the LED effect based on the effect data determined in S410.

Next, the sub CPU 81 executes sound data determination processing (S412). In this process, the sub CPU 81 sets the effect registration information related to the sound effect based on the effect data determined in S410.

Next, the sub CPU 81 registers each determined data (S413) and terminates the command analysis process.

Thus, the sub CPU 81 that determines the effect data based on the communication data output from the main CPU 31, and determines the effect registration information to be executed from a plurality of effect registration information based on the determined effect data. It constitutes effect information determining means in the embodiment.

<Production content determination processing>
FIG. 99 is a flow chart showing effect content determination processing executed in step S410 of the command analysis processing shown in FIG.

First, the sub CPU 81 determines whether or not an initialization command has been received (S430).
Here, if it is determined that the initialization command has been received (YES), the sub CPU 81 executes initialization command reception processing (S431), and ends the effect content determination processing. In the initialization command reception process, for example, effect data based on the information transmitted as the initialization command is set.

On the other hand, when determining that the initialization command has not been received (NO), the sub CPU 81 determines whether or not the medal insertion command has been received (S432). Here, if it is determined that the medal insertion command has been received (YES), the sub CPU 81 executes the medal insertion command reception processing (S433), and ends the effect content determination processing. In the medal insertion command reception process, for example, effect data based on the information transmitted as the medal insertion command is set.

On the other hand, when determining that the medal insertion command has not been received (NO), the sub CPU 81 determines whether or not the start command has been received (S434). Here, if it is determined that the start command has been received (YES), the sub CPU 81 executes the start command reception processing shown in FIG. 100 (S435), and ends the effect content determination processing. In the start command reception process, for example, effect data based on the information transmitted as the start command is set.

On the other hand, when determining that the start command has not been received (NO), the sub CPU 81 determines whether or not the reel rotation start command has been received (S436). Here, if it is determined that the reel rotation start command has been received (YES), the sub CPU 81 executes reel rotation start command reception processing (S437), and ends the effect content determination processing. In the reel rotation start command reception processing, for example, effect data based on the information transmitted as the reel rotation start command is set.

On the other hand, when determining that the reel rotation start command has not been received (NO), the sub CPU 81 determines whether or not the reel stop command has been received (S438). Here, if it is determined that the reel stop command has been received (YES), the sub CPU 81 executes reel stop command reception processing (S439), and ends the effect content determination processing. In the reel rotation start command reception processing, for example, effect data based on the information transmitted as the reel rotation start command is set.

On the other hand, when determining that the reel stop command has not been received (NO), the sub CPU 81 determines whether or not the winning operation command has been received (S440). Here, if it is determined that the winning operation command has been received (YES), the sub CPU 81 executes the winning operation command receiving process shown in FIG. 102 (S441), and ends the effect content determination process. In the winning operation command receiving process, for example, effect data based on the information transmitted as the winning operation command is set.

On the other hand, when determining that the winning operation command has not been received (NO), the sub CPU 81 determines whether or not the bonus start command has been received (S442). Here, if it is determined that the bonus start command has been received (YES), the sub CPU 81 executes bonus start command reception processing (S443), and ends the effect content determination processing. In the bonus start command receiving process, for example, effect data based on the information transmitted as the bonus start command is set.

On the other hand, when determining that the bonus start command has not been received (NO), the sub CPU 81 determines whether or not the bonus end command has been received (S444). Here, if it is determined that the bonus end command has been received (YES), the sub CPU 81 executes bonus end command reception processing (S445), and ends the effect content determination processing. In the bonus end command reception process, for example, effect data based on the information transmitted as the bonus end command is set.

On the other hand, when determining that the bonus end command has not been received (NO), the sub CPU 81 determines whether or not the input state command has been received (S446). Here, if it is determined that the input state command has been received (YES), the sub CPU 81 executes processing when receiving the input state command (S447), and ends the effect content determination processing.

In the input state command reception processing, for example, the main CPU 31 transmits as an input state command whether each operation unit is in the ON edge state or the OFF edge state. On the other hand, if it is determined in S446 that the input state command has not been received (NO), the sub CPU 81 terminates the effect content determination process.

The order of commands received by the sub CPU 81 in the effect content determination process constitutes a predetermined order in the present embodiment. Further, in the present embodiment, the main CPU 31 that transmits various commands to the sub CPU 81 constitutes command transmission means.

<Processing when a start command is received>
FIGS. 100 and 101 are flow charts showing the start command reception process executed in step S435 of the effect content determination process shown in FIG.

First, the sub CPU 81 extracts a random number value for effect, and stores the extracted random number value for effect in the random number value for effect storage area of the sub RAM 83 (S450). Next, the sub CPU 81 determines whether or not the ART gaming state is the ART state (S451).

Here, if it is determined that it is in the ART state (YES), the sub CPU 81 determines whether or not the BB malfunction check flag stored in the sub RAM 83 is ON (S452). Specifically, although the second stop operation order, which is the notification of the winning mode of the predetermined internal winning combination for winning the "RB description", is notified, "BB description 1", "BB It is determined whether or not there is a prize in either "Rep 2" or "RB Rep".

Here, the sub CPU 81 normally should have won "BB description 1", "BB description 2" or "RB description" in the ART state. ), the processing of step S482 or step S485 turns off the BB malfunction check flag when "BB reply 1", "BB reply 2" or "RB reply" is won.

Therefore, the sub CPU 81 determines whether or not the BB malfunction check flag is on, and if it determines that it is on, there is a possibility that a fraudulent act that causes power interruption or line disconnection has been performed. judged to be high.

In the process of step S452, when it is determined that the BB malfunction check flag is ON (YES), the sub CPU 81 determines whether or not the winning combination of the previous game is saved (S453). Specifically, the sub CPU 81 causes the player to win "BB reply 1" or "BB reply 2" despite the fact that the RB reply has been notified, and performs the processing when receiving a winning operation command, which will be described later, in the game. determine whether or not the person has prevented the execution by fraudulent acts. That is, the sub CPU 81 is configured to double-check whether or not a fraudulent act that causes power interruption or line disconnection has been executed by executing the processing of steps S452 and S453. ing.

Here, when it is determined that the winning combination of the previous game is not stored (NO), the sub CPU 81 turns off the BB malfunction check flag (S454) and turns on the navigation prohibition flag (S455). In this process, the sub CPU 81 determines that the player has committed a fraudulent act to prevent the execution of the winning command reception process. Impose a penalty that does not notify the operation order at all.

In the processing of step S452, if it is determined that the BB malfunction check flag is not ON (NO), in the processing of step S453, if it is determined that the winning combination of the previous game is saved (YES), or the processing of step S455 , the sub CPU 81 determines whether or not the navigation prohibition flag is ON (S456). In this process, if it is determined that the navigation prohibition flag is ON (YES), the sub CPU 81 ends the start command reception process.

On the other hand, if it is determined in the process of step S456 that the navigation inhibition flag is off (NO), the sub CPU 81 determines whether the BB malfunction flag stored in the sub RAM 83 is on ( S457). Specifically, the sub CPU 81 determines that the second stop operation order for winning the "BB reply" or "BB reply 1" or "BB reply 2" has been notified. It is determined whether or not "Bonus Rep 1 or 2" is won in the second winning mode (BB Rep 1 or BB Rep 2) according to the first stop operation order.

The BB malfunction flag is turned on when "bonus reply 1 or 2" wins in the second winning mode (BB reply 1 or BB reply 2) despite the notification of the second stop operation order. becomes.

Here, if it is determined that the BB malfunction flag is ON (YES), the sub CPU 81 determines whether or not a sequence error is occurring (S458). Specifically, the sub CPU 81 determines whether or not a sequence error is set in step S402 of the received command check process (see FIG. 97).

In the processing of step S458, if it is determined that a sequence error is occurring (YES), the sub CPU 81 determines that the order of the received commands is abnormal, so that the illegal navigation lottery table (see FIG. 60) , determines navigation data during ART based on the winning combination and the random number value for effect (S459), and ends the start command reception processing.

Specifically, the sub CPU 81 refers to the fraudulent navigation lottery table that informs of the predetermined stop operation information, so that the winning number is determined without changing the number of ART games (70 games) generated by the second winning mode. Penalties are provided such that when 1 and 2 are internally won, stop operation information for winning a normal replay is reported, and when another internal winning combination is internally won, stop operation information for winning a winning combination is not reported. impose. Here, the predetermined stop operation information refers to stop operation information that notifies only the order of stop operations for winning a normal replay, but does not notify the order of stop operations related to other winning combinations.

In the process of step S458, if it is determined that a sequence error is not occurring (NO), the sub CPU 81 refers to the special navigation lottery table (see FIG. 59), and based on the winning combination and the effect random number value, Then, navigation data during ART is determined (S460), and the start command reception processing is terminated.

Specifically, the sub CPU 81 refers to the special navigation lottery table, so that the first stop operation order is notified without changing the number of ART games (70 games) generated by the second prize mode. Advantageous stop operation information (stop operation order) regarding awarding of medals is reported at a lower probability than when "bonus reply 1 or 2" is won in the second prize mode (BB reply 1 or BB reply 2) in the state. do.

More preferably, when the player wins in the second winning mode (BB reply 1 or BB reply 2) due to an erroneous operation or intention of the player, the sub CPU 81 causes the player to win in the first winning mode (RB reply). The stop operation order is notified with a probability that the same number of medals as the medals to be given in the case are given.

On the other hand, if it is determined that the BB malfunction flag is not ON (NO), the sub CPU 81 refers to the normal navigation lottery table (see FIG. 58), and based on the winning combination and the random number for effect, the ART is in progress. The navigation data is determined (S461), and the start command reception process ends. Here, in the present embodiment, the stop operation information notified using the normal navigation lottery table, the special navigation lottery table, or the fraudulent navigation lottery table constitutes the stop operation information beneficial to the player. In addition, in the present embodiment, any one of the winning numbers 4 to 6, 7 to 12, 13 to 18, 19 to 24, and 25 to 30 among the stop operation information notified using the normal navigation lottery table is won. The stop operation information notified when the game is played constitutes specific stop operation information relating to the provision of game media with a predetermined probability.

If it is determined in step S451 that the vehicle is not in the ART state (NO), the sub CPU 81 turns off the navigation inhibition flag (S462) and turns off the BB malfunction flag (S463). In this process, the sub CPU 81 cancels the penalty if the penalty for turning on the navigation prohibition flag in the ART state has been imposed.

Next, the sub CPU 81 determines whether or not the notification flag is ON (S464). Here, if it is determined that the notification flag is not ON (NO), the sub CPU 81 terminates the start command reception process.

On the other hand, if it is determined that the notification flag is ON (YES), the sub CPU 81 refers to the notification mode lottery table shown in FIG. to determine notification data (notification mode) (S465).

Next, the sub CPU 81 determines whether the decided notification mode is the notification mode C or the notification mode D (S466). If it is determined that the determined notification mode is the notification mode C or the notification mode D (YES), the sub CPU 81 turns ON/OFF the notification lamps 111L and 111R, which will be described later, based on the value of the performance timer. (S467).

By such processing, for example, in step S372 of the LED output control task shown in FIG. 89, an announcement effect based on the effect data for announcement is performed. The notification effect in the present embodiment is performed by notification lamps 111L and 111R.

In addition, in S382 of the sound control task shown in FIG. 92, an announcement effect based on the effect data for announcement may be performed. Also, in both step S372 of the LED output control task shown in FIG. 89 and S382 of the sound control task shown in FIG. 92, an announcement effect based on the effect data for announcement may be performed.

If it is determined in step S466 that the determined notification mode is not notification mode C or notification mode D (NO), or after executing the process of step S467, the sub CPU 81 displays the ART type notification distribution lottery table (Fig. 57), and based on the current release mode and the random number value for effect, the notification distribution is determined (S468). In this way, the sub CPU 81 constitutes a winning mode sorting means.

Next, the sub CPU 81 determines navigation data at the start of ART based on the determined notification distribution and the type of bonus reply (S469). Next, the sub CPU 81 determines whether or not the notification distribution is the RB reply notification (S470).

Here, if it is determined that the notification distribution is not the RB reply notification (NO), the sub CPU 81 terminates the start command reception process. On the other hand, if it is determined that the notification distribution is the RB reply notification (YES), the sub CPU 81 turns on the BB malfunction check flag stored in the sub RAM 83 (S471), and ends the start command reception process. do.

As described above, the pachi-slot machine 1 according to the present embodiment, when the sequence error occurs during communication between the main control circuit 71 and the sub-control circuit 72 and the ART state is entered, the illegal navigation lottery table ( 60), when any one of the winning numbers 4 to 6, 7 to 12, 13 to 18, 19 to 24, and 25 to 30 is won, the winning internal winning combination is stopped. By imposing a penalty for not notifying the information, it is possible to prevent a fraudulent act from causing a sequence error during communication between the main control circuit 71 and the sub-control circuit 72 and illegally obtaining a game profit.

In addition, the pachi-slot machine 1 according to the present embodiment wins BB reply 1 or BB reply 2 and wins BB reply 1 or BB reply 2 when RB reply is notified. , and a sequence error occurs during communication between the main control circuit 71 and the sub-control circuit 72, the illegal navigation lottery table (see FIG. 60) is used. , if any one of the winning numbers 4-6, 7-12, 13-18, 19-24, 25-30 is won, a penalty is imposed not to notify the stop operation information for winning each winning internal winning combination. As a result, it is possible to prevent illegal acquisition of profits that can be obtained by winning BB Lip 1 or BB Lip 2.

Further, in the pachi-slot machine 1 according to the present embodiment, the ART state can be prevented by executing a fraudulent act during communication between the main control circuit 71 and the sub-control circuit 72 so as not to cause the sub-control circuit 72 to detect the winning combination. By imposing a penalty of not notifying the stop operation information in , it is possible to prevent fraudulent behavior from causing a sequence error during communication between the main control circuit 71 and the sub-control circuit 72 and illegally obtaining game profits. can.

Further, the pachi-slot machine 1 according to the present embodiment, when the RB reply is notified, causes the winning of the BB reply 1 or the BB reply 2 different from the RB reply, and the winning of the BB reply 1 or the BB reply 2. By imposing a penalty not to notify the stop operation information in the ART state by imposing a penalty not to notify the stop operation information in the ART state by executing fraud during communication between the main control circuit 71 and the sub control circuit 72 so that the sub control circuit 72 does not detect it It is possible to prevent a sequence error from occurring during communication between the main control circuit 71 and the sub-control circuit 72, thereby preventing illegal gaining of game profits.

Further, in the present embodiment, the sub CPU 81 constitutes a prize mode notification means and a prize mode determination means.

<Processing when winning operation command is received>
FIG. 102 is a flow chart showing the winning actuation command reception process executed in step S441 of the effect content determination process shown in FIG.

First, the sub CPU 81 determines whether or not the BB malfunction check flag is ON (S480). Here, if it is determined that the BB malfunction check flag is ON (YES), the sub CPU 81 determines whether or not BB description 1 or BB description 2 has been won (S481).

In the processing of step S481, if it is determined that BB description 1 or BB description 2 has been won (YES), the sub CPU 81 turns off the BB malfunction check flag (S482) and turns on the BB malfunction flag. (S483). In this process, the sub CPU 81 turns on the BB malfunction flag because BB reply 1 or BB reply 2 has won although the RB reply has been notified.

On the other hand, when it is determined in the process of step S481 that BB descriptor 1 and BB descriptor 2 have not been won (NO), the sub CPU 81 determines whether RB descriptor has been won (S484). In this process, if it is determined that the RB reply has won (YES), the RB reply has been notified and the RB reply has won, so the BB malfunction check flag is turned off (S485).

In the process of step S480, if the BB malfunction check flag is off (NO), in the process of step S484, if the RB reply has not won (NO), or after executing the process of step S485, the sub CPU 81 , Save the established winning combination (S486) In this process, the sub CPU 81 stores the established winning combination in the winning combination storage area of the sub RAM 83, which is an area for storing the winning combination. The winning combination storage area is cleared by the sub CPU 81 when the reel rotation start command is received.

Next, the sub CPU 81 sets effect data based on the established winning combination (S487), and terminates the winning command reception process. In this process, the sub CPU 81 sets the effect number related to the sound data and the LED effect data to be executed based on the established winning combination.

Thus, in the present embodiment, the sub CPU 81 constitutes winning combination storage means.

As described above, the pachi-slot machine 1 according to the present embodiment stores the sound data set to type "1" from the sub-ROM 82 to the audio RAM 85 when the sub-control circuit 72 is activated, and causes the DSP 84 to execute the sound data. By changing the transfer source of the sound data according to the type of , it is possible to prevent the transfer of the sound data from causing a problem in responsiveness, and it is possible to execute an effect that satisfies the required responsiveness.

Further, the pachi-slot machine 1 according to the present embodiment stores the sound data set to type "1", which is often executed by the DSP 84 and requires high responsiveness, when the sub-control circuit 72 is activated, the sub-ROM 82 is stored in the audio RAM 85 and executed, the sound data set to type "1" is transferred from the audio RAM 85 to the DSP 84 and executed. can be prevented, and an effect that satisfies the required responsiveness can be executed.

Further, in the pachi-slot machine 1 according to the present embodiment, when the DSP 84 wants to continuously execute a plurality of sound data, the sound sequence is stored in advance in the sound sequence table of the sub ROM 82, and the sound sequence is selected. Since multiple sound data can be executed continuously by using A production that satisfies the required responsiveness can be executed.

Therefore, in the pachi-slot machine 1 according to the present embodiment, for example, when confirming the behavior of the pachi-slot machine 1 when playing a plurality of arbitrary sound data in succession, it is set that a predetermined condition has been established. By creating a sound sequence composed of a plurality of arbitrary sound data, the behavior of the pachi-slot machine 1 can be confirmed, and the sound data can be easily confirmed and corrected.

Further, in the pachi-slot machine 1 according to the present embodiment, the LED effect data is associated with the sound data, the sound data is being executed, and the LED effect data associated with the sound data being executed is executed. If not, the associated LED effect data is transferred from the sub ROM 82 to the sub CPU 81 and executed. can prevent an increase in

Further, in the pachi-slot machine 1 according to the present embodiment, if the LED effect data associated with the sound data being executed is not being executed during the period from the start of execution of the sound data until the predetermined reproduction time elapses. , Since the sub CPU 81 manages the execution of sound data, it is not necessary to determine whether the sound data is being executed each time, the number of times control processing is executed can be reduced, and the occurrence of bugs can be suppressed. be able to.

In a conventional game machine, when a plurality of sound effects are executed in one effect, it is necessary to determine and execute the effect to make the game machine emit light each time the sound changes. It was necessary to set such a configuration and a configuration related to the effect of causing the gaming machine to emit light for each effect. For this reason, in the conventional game machine, the configuration related to the sound effect and the configuration related to the light emitting effect of the game machine are separated. In addition, it is necessary to change and modify both the configuration related to the sound effect and the configuration related to the lighting effect of the game machine, which increases the number of design man-hours required for the change and may cause bugs after commercialization. There was a problem with the increase In order to solve this problem, the pachi-slot machine 1 according to the present embodiment prioritizes new LED effect data when new LED effect data is transferred even during execution of the LED effect data. Therefore, when the sound data is executed, the LED effect data associated with the sound data can be reliably executed. Therefore, it is possible to easily confirm whether or not the design is to be implemented, thereby reducing design man-hours and suppressing the occurrence of bugs.

[Configuration of pachinko machine]
The present invention is not limited to pachislot machines, but can also be applied to pachinko machines. The pachinko game machine will be described below.

As shown in FIGS. 103 and 104, a pachinko machine 1010 as a game machine includes a glass door 1011, a wooden frame 1012, a base door 1013, a game board 1014, a plate unit 1020, a liquid crystal display device 1032 for displaying images, and game balls. , a dispensing unit (not shown), a substrate unit, and the like.

The glass door 1011 is attached to the base door 1013 so as to be openable and closable by a rotating shaft. An opening 1011a is formed in the center of the glass door 1011, and a transparent protective glass 1019 is arranged in the opening 1011a.

The tray unit 1020 is a unit body in which the upper tray 1021 and the lower tray 1022 are integrated, and is arranged below the glass door 1011 in the base door 1013 . The upper plate 1021 and the lower plate 1022 are formed with payout openings 1021a and 1022a for lending game balls and paying out game balls (prize balls). Balls are discharged, and in particular, game balls to be shot to a game area 1015 described later are stored in the upper tray 1021 .

Firing device 1130 is disposed in the lower right portion of base door 1013 and includes a firing handle 1026 operable by the player and a panel body 1027 that fits in the lower right portion of dish unit 1020 . A firing handle 1026 is provided on the front side of the panel body 1027 .
A driving device for shooting game balls is provided on the back side of the panel body 1027 . The player can shoot the game ball by operating the shooting handle 1026 to advance the game.

The game board 1014 is arranged in front of the base door 1013 so as to be positioned behind the protective glass 1019 . A liquid crystal display device 1032 and the like are arranged behind the game board 1014 . A payout unit and a board unit are arranged behind the base door 1013 . Under the lower plate 1022, a speaker 1046 (see FIG. 105) for presentation is arranged.

The game board 1014 is entirely made of transparent plate-shaped acrylic resin, polycarbonate resin, methacrylic resin, and other various resins (members having transparency).
In addition, the game board 1014 has a game area 1015 on the front side thereof, in which the launched game ball can roll and flow. A plurality of game nails 1017 are driven into the game area 1015 . Also, an LED unit 1053 is provided in the lower left part of the game board 1014 .

The liquid crystal display device 1032 is arranged behind the game board 1014 (back side). The liquid crystal display device 1032 has a display area 1032a capable of displaying images related to games. In the display area 1032a, various images such as an identification pattern for presentation, a presentation image, and a decoration image for decoration are displayed.

The firing handle 1026 is rotatable and has a firing solenoid (not shown) as a driving device on its back side. Further, a touch sensor (not shown) is provided on the periphery of the firing handle 1026 . Inside the firing handle 1026 is provided a firing volume that changes the resistance value according to the amount of rotation of the firing handle 1026 to change the power supplied to the firing solenoid (not shown).

When the player touches a touch sensor (not shown), it is detected that the shooting handle 1026 is gripped by the player. When the shooting handle 1026 is gripped by the player and rotated clockwise, the resistance value of the shooting volume (not shown) changes according to the rotation angle, and corresponds to the resistance value at this time. Power is supplied to a firing solenoid (not shown). As a result, the game balls stored in the upper tray 1021 are sequentially shot to the game area 1015, and the game proceeds. When a shooting stop button (not shown) is pressed, shooting of the game ball is stopped even when the shooting handle 1026 is gripped and rotated.

Members forming general prize winning openings 1056a, 1056b, and 1056c are arranged in the lower left portion of the game board 1014, and the portions of these members facing the LED unit 1053 are transparent. Therefore, the LED unit 1053 can be visually recognized from the lower left side of the game board 1014 . The LED unit 1053 includes the special symbol display device illustrated in FIG. 105, the normal symbol display device 1033, the first special symbol reservation display LEDs 1034a and 1034b, the second special symbol reservation display LEDs 1034c and 1034d, the normal symbol reservation display LEDs 1050a and 1050b, and the like. is provided.

The special symbol display device is composed of 16 LEDs. These 16 LEDs are divided into two groups consisting of 8 LEDs, one group performs a variable display triggered by the start winning to the first start port 1023, the other group , and the second start port 1044 is used as a trigger to perform a variable display. For convenience of explanation below, one group of LEDs is called a first special symbol display device 1035a (see FIG. 105), and the other group of LEDs is called a second special symbol display device 1035b (see FIG. 105).

The LEDs of the first and second special symbol display devices 1035a and 1035b perform variable display of special symbols by repeating lighting and extinguishing on a group basis when predetermined special symbol variable display start conditions are established. Then, when the special symbols are in a specific stop display mode, the game state shifts from the normal game state to a winning game state (special game state) which is advantageous to the player. When the winning game state is entered, the shutter 1040 is controlled to be open as will be described later, and a game ball can be received in the big winning opening 1039 .

The normal symbol display device 1033 alternately turns on and off the two display lamps to display the normal symbols in a variable manner.

The normal symbol pending display LEDs 1050a and 1050b display the number of executions of variable display of normal symbols suspended by lighting, extinguishing or blinking (so-called "holding number", "holding number regarding normal symbols").

The first special symbol reserved display LEDs 1034a, 1034b and the second special symbol reserved display LEDs 1034c, 1034d are the number of executions of the variable display of special symbols reserved by lighting, extinguishing or blinking (so-called "number of reservations", "special symbols number of items on hold”).

Also, in the display area of the liquid crystal display device 1032, effect images related to the special symbols displayed on the first special symbol display device 1035a and the second special symbol display device 1035b are displayed.

As shown in FIG. 104, on the game board 1014, there are two guide rails 1030 (1030a and 1030b), a stage 1055, a first starting port 1023, a second starting port 1044, a passage gate 1054, a shutter 1040, and a prize winning port. 1039, general prize-winning ports 1056a, 1056b, 1056c, 1056d, ordinary electric accessories 1048, and the like are provided. Here, in the present embodiment, the first starting port 1023 and the second starting port 1044 constitute a detection area.

A stage 1055 is provided above the game board 1014 , and a guide rail 1030 is provided so as to surround the game area 1015 .

The guide rail 1030 is composed of an outer rail 1030a and an inner rail 1030b. The shot game ball is guided by the guide rail 1030, moves to the upper part of the game board 1014, and changes its traveling direction by colliding with the above-described plurality of game nails (not shown), the stage 1055, and the like. It flows downward on the game board 1014 . Specifically, the system that flows down the left side of the stage 1055 (so-called left-handed hitting) and the shooting handle 1026 are rotated to the right to the maximum to hit the game ball on the right side of the stage 1055 and flow down the right side of the stage 1055. There is a system (so-called right-handed).

The first starting port 1023 is provided below the center of the game board 1014 . A pass gate 1054 is provided on the upper right side of the stage 1055 , and a second starting port 1044 is provided below the pass gate 1054 . A normal electric accessory 1048 is provided at the second starting port 1044 .

In addition, the normal electric accessory 1048 has a tongue-shaped member 1048a that protrudes and retracts in the front-rear direction with respect to the game board surface. The ordinary electric accessory 1048 allows a game ball to enter the second start port 1044 when the tongue member 1048a is protruded, and disables a game ball to enter the second start port 1044 when the tongue member 1048a is retracted. Incidentally, the normal electric accessory 1048 may be one in which a pair of blade members are opened and closed (so-called electric tulip).

In addition, the game nail 1017 prevents the game ball from entering the first starting port 1023 from the right side of the stage 1055 when hitting to the right.

In addition, when the game ball passes through the passage gate 1054 during the variable display of the normal symbols, the display mode by the normal symbol reservation display LEDs 1050a and 1050b is switched, and the normal symbols during the variable display are stopped and displayed. The execution (start) of the variable display of normal symbols based on the passage of the game ball to the passage gate 1054 is suspended. After that, when the variable-displayed normal symbols are stopped and displayed, the variable display of the suspended normal symbols is started.

When a specific symbol is stopped and displayed as a normal symbol on the normal symbol display device 1033, an effect image is displayed in the display area of the liquid crystal display device 1032 to make the player understand that the normal symbol lottery is won. You may do so.

Further, the shutter 1040 is arranged directly below the first starting opening 1023 and opens and closes the big winning opening 1039 . An out port 1057 is formed at the lowest part of the game area 1015 directly below the shutter 1040 . General winning openings 1056 a , 1056 b , 1056 c are provided in the lower left part of the game area 1015 . Also, in the lower right portion of the game area 1015, a general prize winning opening 1056d is provided.

Also, a winning area is provided in the above-described first starting opening 1023, and a first starting winning opening switch 1116 (see FIG. 105) is provided in this winning area. A winning area is provided in the second starting opening 1044, and the second starting winning opening switch 1117 (see FIG. 105) is provided in this winning area. When the game ball is detected by the first start winning opening switch 1116, the variable display of the special symbols by the first special symbol display device 1035a is started.

In addition, when the game ball enters the first start port 1023 during the variable display of the special symbol, the game ball enters the first start port 1023 until the special symbol during the variable display is stopped and displayed. Execution (start) of variable display of special symbols based on is suspended. After that, when the variable display of the special symbol is stopped and displayed, the variable display of the reserved special symbol is started. In the following description, the special symbol that is variably displayed on the first special symbol display device 1035a based on the entry of the game ball into the first starting port 1023 is called the first special symbol.

Also, when the game ball is detected by the second start winning opening switch 1117, the second special symbol display device 1035b starts the variable display of the special symbols. In addition, when the game ball enters the second starting port 1044 during the variable display of the special symbol, the game ball enters the second starting port 1044 until the special symbol during the variable display is stopped and displayed. Execution (start) of variable display of special symbols based on is suspended. After that, when the variable display of the special symbols is stopped and displayed, the variable display of the reserved special symbols is started. In the following description, the special symbol that is variably displayed on the second special symbol display device 1035b based on the entry of the game ball into the second starting port 1044 is referred to as the second special symbol.

Here, the first special symbol display device 1035a and the second special symbol display device 1035b do not change the special symbols at the same time. In addition, the variable display of the special symbol is performed with priority given to the start winning to the second start port 1044. - 特許庁

In addition, the number of suspensions of the variable display of the special symbol due to the ball entering the first starting port 1023 and the second starting port 1044 has an upper limit of 4 times. Therefore, a maximum of 8 holds is possible.

In addition, another (predetermined special symbol variable display start) condition is that the special symbol is stopped and displayed. In other words, the variable display of the special symbols is started each time the condition for starting the variable display of the predetermined special symbols is satisfied.

In the first special symbol display device 1035a and the second special symbol display device 1035b, the special symbol becomes a specific stop display mode, and when the game state is shifted to the jackpot game state, the shutter 1040 is opened. driven. As a result, the big winning opening 1039 becomes an open state (first state) in which it is easy to receive game balls.

On the other hand, the large winning opening 1039 provided on the back side (rear) of the shutter 1040 has an area (not shown) having a count switch 1104 (see FIG. 105), and a predetermined number of game balls (for example, 7), or the shutter 1040 is driven open until a predetermined time (for example, about 0.1 second or about 30 seconds) elapses. Then, when either condition of winning of a predetermined number of game balls into the big winning opening 1039 or elapse of a predetermined time is established in the open state, the shutter 1040 is driven to be in the closed state. As a result, the big winning opening 1039 is in a closed state in which it is difficult to accept game balls (second state).

A round game is a game in which the big winning hole 1039 is in a state where it is easy to accept game balls for a certain period of time. Therefore, the shutter 1040 is opened during round games and closed between round games. A round game is counted as the number of rounds such as "1" round, "2" round, and the like. For example, the first round game may be called the first round, and the second round game may be called the second round. In this example, in one round, the shutter 1040 may be opened and closed multiple times, and the time during which the shutter 1040 is in the open state may be a certain period of time.

Subsequently, the shutter 1040 driven from the open state to the closed state (second state) is driven to the open state again. That is, when the round game ends, it is possible to continue to the next round game. A game from the first round game to the end of the (final) round game in which the next round game cannot be continued is called a special game or a jackpot game. Note that in this example, all jackpots are 15 rounds.

In addition, when the game ball wins in the above-described first starting port 1023, second starting port 1044, general winning ports 1056a to 1056d, and big winning port 1039, the number preset according to the type of each winning port of game balls are paid out to the upper tray 1021 or the lower tray 1022.例文帳に追加

Also, in this example, after the jackpot game is over, the winning probability of the normal symbol lottery becomes a high probability state, and the support of the normal electric accessory 1048 may shift to a time saving state in which the reserved balls of the special symbol game are easily accumulated. . Here, in the time-saving state, passing the game ball through the passage gate 1054 is a condition for executing the normal symbol lottery, so the game proceeds while hitting to the right.

Also, when a big hit occurs in the right-handed state, it is possible to win a prize to the big winning opening 1039 by continuing the right-handed hit. In addition, when the support by the normal electric accessory 1048 cannot be received, the game is progressed while hitting to the left.

In addition, as shown in FIG. 103, on the front surface of the upper tray 1021, effect buttons 1080a, 1080b, 1080c are provided. By pressing the button, the effect display contents on the liquid crystal display device 1032 can be changed.

In the pachinko machine 1010, a liquid crystal display device is described as an example of the rendering means, but the present invention is not limited to this, and includes a plasma display, a rear projection display, a CRT display, lamps/LEDs 1132 shown in FIG. You may use peripheral devices, such as, as a production|presentation means.

Next, the electrical configuration of the pachinko machine 1010 will be described with reference to FIG.

As shown in FIG. 105, the pachinko machine 1010 is mainly composed of a main control circuit 1060 for controlling games and a sub-control circuit 1200 for controlling effects according to the progress of the games.

The main control circuit 1060 includes a main CPU 1066, a main ROM 1068 (read-only memory), and a main RAM 1070 (readable/writable memory).

The main CPU 1066 has the same configuration as the main CPU 31 (see FIG. 8) described in the pachi-slot gaming machine of the present embodiment. In other words, the main CPU 1066 constitutes information output means for outputting various commands as information relating to the progress of the game to the sub-control circuit 1200 via the command output port 1060, and also executes various processes relating to the progress of the game. ing. Specifically, the main CPU 1066 detects that the game ball has passed through the first starting opening 1023 by the first starting winning opening switch 1116 described later, or the second starting opening 1044 by the second starting winning opening switch 1117. A lottery means is configured to lottery whether or not to shift the game state to a jackpot state, which is a game state advantageous to the player, when it is detected that the game ball has passed.

A main ROM 1068 , a main RAM 1070 , etc. are connected to the main CPU 1066 , and has a function of executing various processes according to programs stored in the main ROM 1068 .

The main ROM 1068 stores a program for controlling the operation of the pachinko machine 1010 by the main CPU 1066, a program for causing the main CPU 1066 to execute main processing, various tables, and the like.

The main RAM 1070 has a function of storing various flags and variable values as a temporary storage area for the main CPU 1066 . The temporary storage area of the main CPU 1066 is not limited to the main RAM 1070, and other readable and writable storage media may be used.

The main control circuit 1060 also includes an initial reset circuit 1064 that generates a reset signal when power is turned on, an I/O port 1071 and a command output port 1072 . Also, the initial reset circuit 1064 is connected to the main CPU 1066 . The I/O port 1071 transmits input signals from various devices to the main CPU 1066, and transmits output signals from the main CPU 1066 to various devices.

The command output port 1072 transmits commands from the main CPU 1066 to the sub control circuit 1200 . The main control circuit 1060 also has a backup capacitor 1074 . The backup capacitor 1074 is used to retain various data stored in the main RAM 1070 by, for example, rapidly supplying power to the main RAM 1070 when power is cut off.

Various devices are connected to the main control circuit 1060 . For example, the main control circuit 1060 includes the first special symbol display device 1035a and the second special symbol display device 1035b, the first special symbol reservation display LEDs 1034a and 1034b and the second special symbol reservation display LEDs 1034c and 1034d, and the normal symbol display device 1033. , normal pattern holding display LEDs 1050a, 1050b, normal electric accessory 1048 tongue-shaped member 1048a in protruded state or retracted state start opening solenoid 1118, shutter 1040 is driven, large winning opening 1039 is opened or closed. A big winning opening solenoid 1120 and the like are connected.

The main control circuit 1060 also includes a calling device (not shown) having a function of calling a hall attendant and displaying the number of hits, and an external terminal used to transmit data to the hall computer 1400 that manages the pachinko machines in the entire hall. A plate 1310 is connected.

In addition, the main control circuit 1060 includes, for example, a count switch 1104 that supplies a predetermined detection signal to the main control circuit 1060 when a game ball passes through the area of the large winning opening 1039, When the game ball passes through the general winning port switches 1106, 1108, 1110, 1112 and the passage gate 1054, which supplies a predetermined detection signal to the main control circuit 60, the main control circuit outputs a predetermined detection signal. Pass gate switch 1114 supplied to 1060, first start winning opening switch 1116 to supply a predetermined detection signal to main control circuit 1060, second starting opening 1044 when game ball wins first starting opening 1023 A second start prize winning port switch 1117 that supplies a predetermined detection signal to the main control circuit 1060 when a ball wins a prize, and a backup clear switch that clears backup data in the event of a power failure or the like according to the operation of the manager of the game arcade. 1124 and the like are connected.

A payout/launch control circuit 1126 is connected to the main control circuit 1060 . The payout/shooting control circuit 1126 is connected with a payout device 1128 for putting out game balls, a shooting device 1130 for shooting game balls, and a card unit 1300 . The card unit 1300 can be transmitted and received to and from a ball lending operation panel 1155 that outputs a signal requesting the card unit 1300 to lend a game ball by a player's operation.

The payout/launch control circuit 1126 receives the prize ball control command supplied from the main control circuit 1060 and the ball rental control signal supplied from the card unit 1300, and transmits a predetermined signal to the payout device 1128. The payout device 1128 is caused to pay out game balls.
In addition, the payout/shooting control circuit 1126 supplies electric power to the shooting solenoid according to the rotation angle when the shooting handle 1026 is gripped by the player and is rotated clockwise, and the game is played. Controls the shooting of the ball.

A sub-control circuit 1200 is connected to the command output port 1072 . The sub-control circuit 1200 includes a sub-ROM 1202, a sub-RAM 1203, a DSP 1204, an audio RAM 1205 and a digital amplifier 1206, similar to the sub-control circuit 70 (see FIG. 10) described in the pachislot machine of the present embodiment. Various processes similar to those of the sub-control circuit 70 can be executed. The sub CPU 1201 constitutes effect information determination means, effect information execution means, second effect information execution means, effect information transfer means, effect information group transfer means, and effect information determination means according to the present invention. Also, the sub ROM 1202 constitutes effect information storage means and effect information group storage means according to the present invention. Further, the DSP 1204 constitutes effect information execution means and first effect information execution means according to the present invention. Also, the audio RAM 1205 constitutes specific effect information storage means according to the present invention.

As explained above, according to the pachinko gaming machine according to the present embodiment, it is possible to obtain the same effect as the pachislot gaming machine according to the above embodiment.

1 Pachislot machine (game machine)
3L, 3C, 3R reel (variable display)
4L, 4C, 4R display window (symbol display means)
6 start lever 6S start switch (start operation detection means)
7L, 7C, 7R stop button (stop operation detection means)
7S stop switch (stop operation detection means)
8c winning line 9L, 9R, 1046 speakers (peripheral equipment, effect executing means)
11 BET button 11S BET switch 31, 1066 Main CPU (internal winning combination determination means, winning determination means, information output means, lottery means, combination determination means, lock execution means)
39 Motor drive circuit (symbol variation means, reel stop control means, stop control means)
40 hopper 42S medal sensor 49L, 49C, 49R stepping motor (reel stop control means, stop control means)
50 reel position detection circuit 71, 1060 main control circuit 72, 1200 sub control circuit 81, 1201 sub CPU (effect information determination means, effect information execution means, second effect information execution means, effect information transfer means, effect information group transfer means, effect information determination means, effect determination means)
82, 1202 Sub ROM (effect information storage means, effect information group storage means)
84, 1204 DSP (effect information executing means, first effect information executing means)
85, 1205 Audio RAM (specific effect information storage means)
100-dot display (peripheral equipment, production execution means, production execution unit)
101 reel upper display (peripheral device)
103 reel effect display device (peripheral device, effect execution unit)
104 Side effect display (peripheral device)
105 reel lower indicator (peripheral device, stop operation notification means)
105L, 105C, 105R Digital display section 110 Front panel 111 Notification section (notification means)
330 light emitting unit (peripheral device)
1010 Pachinko machines (game machines)
1014 game board 1015 game area 1023 first starting port (detection area)
1044 Second start port (detection area)
1132 Lamps/LEDs (Peripherals)

Claims (1)

Provided with a variable display part capable of variably displaying a plurality of pieces of identification information in a plurality of display columns, and by starting and then stopping the variable display on the variable display part, it is possible to derive a result display and to provide benefits according to the result display. A game machine that can be granted,
a start operation detection means capable of detecting a game start operation;
a winning combination determination means capable of determining a winning combination from a plurality of combinations including a specific combination that cannot be carried over;
stop operation detection means capable of detecting a stop operation for stopping the variable display of the variable display unit;
stop control means for stopping the variable display of the variable display unit according to the winning combination determined by the winning combination determination means and the stop operation mode detected by the stop operation detection means;
State control means capable of controlling a specific game state in which a stop operation mode that is advantageous to the player is notified;
lock execution means for locking the progress of the game for a predetermined period of time when a specific result display corresponding to the specific combination is derived in the lock waiting state after notification of the shift to the specific game state; ,
sound output means capable of outputting sound;
sound data storage means storing sound data;
a channel determination means capable of determining a channel according to a game state when outputting the sound data;
When the specific combination is determined as the winning combination by the combination determination means in the lock waiting state, a promotion effect can be executed to encourage a stop operation in a specific mode that can lead to the display of the specified result corresponding to the specific combination. and
The specific result display may not be derived depending on the timing of the stop operation even if the stop operation is performed according to the promotion effect when the specific combination is determined as the winning combination by the combination determining means. configured to be
The specific game state is started after the specific result display is derived and the lock is executed in the lock waiting state, and when the specific result display is not derived and the lock is not executed. is not started and
Even if the specific combination is determined as the winning combination by the combination determining means in the lock waiting state, if the specific result display is not derived and the lock is not executed, the specific result display is derived and the lock is executed. It is possible to maintain the lock wait state until
Sound data corresponding to the promotion effect is output from a first channel,
sound data of a game start sound corresponding to the detection of the start operation by the start operation detection means is output from the second channel;
A gaming machine characterized in that sound data corresponding to BGM during the specific gaming state is output from a third channel.

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