JP2020115989A - Pachinko game machine - Google Patents

Abstract

To provide a game machine capable of achieving further novel amusement in the game machine adopting a concept of creating a game progress state advantageous to a player.SOLUTION: A game machine includes plural kinds of development performances having different possibilities of winning as a result of winning/losing determination and a development performance shift suggestive performance for suggesting a shift to either development performance from among the plural kinds of development performances, displays plural final display mode candidate patterns that can become one portion of a final display mode in the development performance shift suggestive performance, displays a non-candidate display mode for indicating that one or plural final display mode candidate patterns cannot be selected as one portion of the final display mode depending on a predetermined condition, and is configured so as to be easily shifted to a development performance having a high possibility of winning as a result of winning/losing determination as the number of final display mode candidate patterns reaching a non-candidate display mode is larger in the development performance shift suggestive pattern.SELECTED DRAWING: Figure 91

Description

Pachinko game machines.

In recent years, as a pachinko game machine, a jackpot lottery with a predetermined probability is triggered when a game ball enters the starting opening on the game board surface (gaming area), and if the jackpot lottery is won, a jackpot (special game ) Transition to the state, the mainstream is Pachinko machines that can win a large number of prize balls by opening the big prize hole provided on the game board surface. In the pachinko gaming machine configured in this way, the probability variation game state that raises the winning probability in the jackpot lottery and the time shortening game state that raises the efficiency of symbol variation for notifying the lottery result in the jackpot lottery There is also a gaming machine which is provided with such as, and which enhances the enjoyment of the game by creating a game progressing state advantageous to the player by these gaming states.

JP 2001-347000 A

However, since there have been many such game machines from the past, there is a problem that development of a model that realizes further novel game play is desired.

Pachinko gaming machine according to this aspect,
A starting opening into which a game ball can enter (for example, a first main game starting opening A10, A10-2),
An identification information display section capable of displaying identification information (for example, a first main game symbol display section A21g),
A main game unit (for example, a main control board M) that controls the progress of the game,
An effect display unit (for example, effect display device SG) capable of displaying effects,
It is provided with a sub game unit (for example, a sub control board S) that controls the effect display on the effect display unit,
The main game department is
Random number acquisition means for acquiring a random number based on the ball entering the starting opening,
When a random number is acquired by the random number acquisition means, a random number temporary storage means for temporarily storing the acquired random number as a hold until the acceptance/rejection determination permission condition is satisfied,
When the acceptance/rejection determination permission condition for a certain hold is satisfied, the acceptance/rejection determination is executed based on the random number related to the certain hold, and the stop display mode of the identification information and the variable display mode of the identification information are determined based on the result of the acceptance/rejection determination. A game content determination means,
According to the determination by the game content determination means, an identification information display control means for controlling the identification information display unit to display the identification information in a variable manner and then stop the identification information.
Special game control means capable of executing a special game in a state advantageous to the player after the result of the determination on the basis of the random number is a win and the identification information is stopped and displayed,
And a game information transmitting means for transmitting to the sub-game unit the game information necessary for effect display executed on the sub-game unit side,
The sub-game department
Game information receiving means for receiving the game information transmitted from the main game section side,
Based on the game information received by the game information receiving means, effect display content control means for controlling the effect display content displayed on the effect display unit,
After the production symbols are variably displayed on the production display unit, the production symbol display control means for controlling to display the final display mode of the production symbols on the production display unit,
A plurality of types of development effects (for example, development effect 1) that are different in the possibility that the result of the win/fail judgment is a win
It has a development effect transition suggestion effect (for example, extermination effect) for suggesting which development effect to shift to from among a plurality of types of development effects,
In the development effect transition suggestion effect, a plurality of final display mode candidate symbols that can be a part of the final display mode are displayed, and one or more final display mode candidate symbols are part of the final display mode depending on a predetermined condition (for example, lottery). Is displayed in a non-candidate display mode (for example, the display of "x") that indicates that it cannot be selected as
The larger the number of final display mode candidate symbols that have become non-candidate display modes in the development effect transition suggestion pattern, the more likely it is that the result of the win/fail judgment is a win It is a Pachinko game machine.

According to the pachinko gaming machine according to this aspect, it is possible to realize a more novel gaming property in the gaming machine that adopts the concept of creating a gaming progress state advantageous to the player.

FIG. 1 is a front view of a pachinko game machine according to the present embodiment. FIG. 2 is a rear view of the pachinko game machine according to the present embodiment. FIG. 3 is a perspective view of the prize ball payout unit of the pachinko game machine according to the present embodiment. FIG. 4 is an operation diagram of the prize ball payout unit of the pachinko game machine according to the present embodiment. FIG. 5 is an electrical overall configuration diagram of the pachinko game machine according to the present embodiment. FIG. 6 is a flowchart of a main process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 7 is a flowchart of a setting change process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 8 is a flowchart of a timer interrupt process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 9 is a flowchart of the NMI interrupt process (when the power is cut off) on the main control board side in the pachinko machine according to this embodiment. FIG. 10 is a flowchart of the prize ball payout command transmission control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 11 is a flowchart of the counter payout control board transmission control processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 12 is an image diagram relating to the prize ball payout command and payout related information on the main control board side in the pachinko game machine according to the present embodiment. FIG. 13 is a flowchart of the counter payout control board reception control processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 14 is a flowchart of a ball entry detection process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 15 is a flowchart of the auxiliary game start entrance ball detection process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 16 is a flowchart of the main game starting opening entrance detection process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 17 is a flowchart of the main game starting opening entrance detection process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 18 is a flowchart of the first (second) special winning opening ball detection process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 19 is a flowchart of the general winning opening detection processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 20 is a flowchart of discharge ball detection processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 21 is a flowchart of the out-port entrance detecting process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 22 is a flowchart of the prize ball number determination processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 23 is a flowchart of the auxiliary game content determination random number acquisition process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 24 is a flowchart of the electric accessory driving determination process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 25 is a diagram showing the internal structure of the distribution entrance ball opening in the pachinko game machine according to the present embodiment. FIG. 26 is a flowchart of the distribution member drive control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 27 is a flowchart of the first non-electric auditors product drive control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 28 is a flowchart of the second non-electric auditors product drive control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 29 is a flowchart of a main game content determination random number acquisition process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 30 is a flowchart of the main game symbol display processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 31 is a main game table configuration diagram used in the first (second) main game symbol display process on the main control board side in the pachinko gaming machine according to the present embodiment. 32 is a main game table configuration diagram used in the first main game symbol display process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 33 is a main game table configuration diagram used in the first main game symbol display process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 34 is a main game table configuration diagram used in the first main game symbol display process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 35 is a main game table configuration diagram used in the second main game symbol display process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 36 is a flowchart of the other main game variation control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 37 is a flowchart of a specific game end determination process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 38 is a flowchart of the small hit game control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 39 is a flowchart of the special game control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 40 is a flowchart of the game state determination processing after the end of the special game on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 41 is a flowchart of a special game operating condition determination process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 42 is a flowchart of fraud detection information management processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 43 is a flowchart of the error management process on the main control board side in the pachinko game machine according to this embodiment. FIG. 44 is a flowchart of a firing control signal output process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 45 is a flowchart of an external signal output process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 46 is a flowchart of payout control board side main processing on the payout control board side in the pachinko gaming machine according to the present embodiment. FIG. 47 is a flow chart of error control processing at the time of abnormality detection on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 48 is a flowchart of the payout motor operation abnormality detection error control process on the payout control board side in the pachinko gaming machine according to the present embodiment. FIG. 49 is a flowchart of a payout abnormality detection error control process on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 50 is a flowchart of ball path abnormality detection error control processing on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 51 is a flowchart of a payout motor abnormality detection error control process on the payout control board side in the pachinko gaming machine according to the present embodiment. FIG. 52 is a flowchart of error control processing at the time of detecting a payout stop abnormality on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 53 is a flowchart of the prize ball payout related information transmission/reception process (against the main control board) on the payout control board side in the pachinko gaming machine according to the present embodiment. FIG. 54 is a flowchart of the prize ball payout control processing (at the time of starting prize ball payout/motor drive start) on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 55 is a flowchart of the prize ball payout control process (at the end of motor driving/at the end of prize ball payout) on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 56 is a flowchart of prize ball payout control processing (at the time of motor drive execution) on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 57 is a flowchart of processing at the time of a motor error on the payout control board side in the pachinko gaming machine according to the present embodiment. FIG. 58 is a main flowchart on the sub-main control unit side in the pachinko gaming machine according to the present embodiment. FIG. 59 is a flowchart of the customization control process on the sub-main control unit side in the pachinko gaming machine according to the present embodiment. FIG. 60 is a flowchart of the customization guide screen display control process on the sub-main control unit side in the pachinko game machine according to the present embodiment. FIG. 61 is a customization guide screen image diagram 1 in the pachinko gaming machine according to the present embodiment. FIG. 62 is a flowchart of the customization-in-progress display control process on the sub-main control unit side in the pachinko gaming machine according to the present embodiment. FIG. 63 is a customization guide screen image diagram 2 in the pachinko game machine according to the present embodiment. FIG. 64 is a customization screen image diagram in the pachinko game machine according to the present embodiment. FIG. 65 is a diagram showing the occurrence probability for each occurrence frequency in the pachinko game machine according to the present embodiment. FIG. 66 is an image diagram of customization during change in the pachinko game machine according to the present embodiment. FIG. 67 is a flowchart of in-game customization control processing on the sub-main control unit side in the pachinko gaming machine according to the present embodiment. FIG. 68 is a flowchart of the pending information management process on the sub-main control unit side in the pachinko game machine according to the present embodiment. FIG. 69 is a flowchart of a first main game prefetching determination process on the sub-main control unit side in the pachinko gaming machine according to the present embodiment. FIG. 70 is a configuration diagram of a prefetch lottery table in the pachinko gaming machine according to the present embodiment. FIG. 71 is a flowchart of the prefetch pending content determination processing on the sub-main control unit side in the pachinko gaming machine according to the present embodiment. FIG. 72 is an example of the pending change scenario determination table in the pachinko gaming machine according to the present embodiment. FIG. 73 is a flowchart of the decorative symbol display content determination processing on the sub-main control unit side in the pachinko game machine according to the present embodiment. FIG. 74 is a flowchart of the effect content determination process on the sub-main control unit side in the pachinko game machine according to the present embodiment. FIG. 75 is a flowchart of the decorative symbol display control process on the sub-main control unit side in the pachinko game machine according to the present embodiment. FIG. 76 is a flowchart of the pending change effect execution process on the sub-main control unit side in the pachinko game machine according to the present embodiment. FIG. 77 is a holding change effect execution image diagram on the sub-main control unit side in the pachinko game machine according to the present embodiment. 78 is a flowchart of special game-related display control processing on the sub-main control unit side in the pachinko gaming machine according to the present embodiment. FIG. 79 is a game state transition diagram in the pachinko gaming machine according to the present embodiment. FIG. 80 is a timing chart of a game state transition and a small hit in the pachinko game machine according to the present embodiment. FIG. 81 is an image diagram of a standby mode and rush mode display screen in the pachinko game machine according to the present embodiment. FIG. 82 is an image diagram of button effects during the big hit game in the pachinko gaming machine according to the present embodiment. FIG. 83 is a diagram showing the flow-down ratio of the game balls in the pachinko game machine according to the present embodiment. FIG. 84 is a transition diagram of stages and stage levels in the pachinko game machine according to the present embodiment. FIG. 85 is a timing chart of stage level-up within one variation in the pachinko game machine according to the present embodiment. FIG. 86 is an image diagram of stage level up before tempai in the pachinko game machine according to the present embodiment. FIG. 87 is a diagram showing a lottery method of advance notice in the fluctuation in which the stage level increases in the pachinko game machine according to the present embodiment. FIG. 88 is an image diagram of stage level up by prefetching effect in the pachinko game machine according to the present embodiment. FIG. 89 is a configuration diagram of a pattern lottery table for stage level up by prefetching effect in the pachinko game machine according to the present embodiment. FIG. 90 is a timing chart of the destruction effect in the pachinko game machine according to the present embodiment. FIG. 91 is an image diagram showing the flow of the destruction effect when the character A is selected in the pachinko game machine according to the present embodiment. FIG. 92 is an image diagram showing the flow of the destruction effect when the character B is selected in the pachinko game machine according to the present embodiment. FIG. 93 is a configuration diagram of a chance scenario determination table in the pachinko game machine according to the present embodiment. FIG. 94 is an image diagram showing the flow of chances in the pachinko game machine according to the present embodiment. FIG. 95 is an image diagram showing a flow of effects of a pattern in which the chance eye ends midway in the pachinko game machine according to the present embodiment. FIG. 96 is an image diagram showing a flow of effect of a pattern in which the display of the first chance ends and the pattern is restored in the pachinko game machine according to the present embodiment. FIG. 97 is a modification example of the configuration diagram of the prefetch lottery table in the pachinko gaming machine according to the present embodiment. FIG. 98 is an image diagram of a modification example of chance chances in the pachinko game machine according to the present embodiment.

Form for carrying out

First, the meaning of each term in this specification will be described. "Entering a ball" includes not only winning in which prize balls are paid out, but also passing through a "through chucker" in which prize balls are not paid out. The “identification information” may be in any form as long as it can identify the type of information through the five senses (visual, auditory, tactile, etc.), but is preferably visual, such as numbers, letters, and patterns. And the like. In addition, in the present specification, the "identification information" may be referred to as a main game design/special design (special drawing) or a decorative design (construction drawing), but the "special design (special drawing)" is a main control board. The display information is identification information controlled by the side, and the "decorative pattern (design)" is identification information as an effect displayed on the sub-control board side. The "display of identification information" is not limited to any display method, and includes, for example, light emission of a light emitting means (for example, liquid crystal, LED, 7-segment) (including not only light emission but also color difference), physical Display (for example, a symbol drawn on the reel band is stopped and displayed at a predetermined position) and the like. The "open state, open state" and "closed state, closed state" are, for example, in a general big winning opening (so-called attacker) configuration, open state = easy winning state, closed state = non-winning state. It will be in an easy state. Further, for example, a state of protruding from the game board (player side) (hereinafter, may be referred to as an advancing state) and a state of retracting inside the game board (opposite side of the player side) (hereinafter, referred to as a retracted state) In a configuration (so-called Vero-type attacker) that can take "there is", the advancing state = easy winning state, and the withdrawal state = non-winning state. "Random number" is a random number used in a lottery (a lottery by an electronic computer) for deciding a certain game content in a pachinko game machine, and includes pseudo random numbers in addition to random numbers in the narrow sense (for example, hard random numbers Soft numbers as random numbers and pseudo-random numbers). For example, the so-called "basic random number" that affects the result of the game, specifically, the "winning random number (random number for winning/winning lottery)" related to the transition of the special game, the variation mode (or variation time) of the identification symbol is determined. "Variation mode determination random number" to do, "Symbol determination random number" to determine stop symbol, "Hit symbol determination random number" to determine whether to move to a specific game (for example, probability variation game) after special game, etc. be able to. When determining the contents of the variation mode and the contents of the final identification information, it is not necessary to use all of these random numbers, and at least one random number that is the same or different from each other may be used. In this specification, the number of random numbers may be displayed in the form of the number of random numbers or a plurality of random numbers. However, once the entrance (for example, starting entrance) that triggers the acquisition of random numbers The random number acquired by entering the ball is called one (that is, in the above example, a bundle of random numbers including winning random number + variation mode determination random number + symbol determination random number... Is called one random number) .. Further, for example, one type of random number (for example, a winning random number) may also serve as another type of random number (for example, a symbol determining random number). The "gaming state" is, for example, a special gaming state in which the special winning opening may be opened, a transition to the special gaming state, a transition to the special gaming state rather than a non-probability variation gaming state in which the lottery probability is a predetermined value. Probability variation with a high probability of lottery game state, transition to special game Auxiliary game state with assistance for winning in the starting mouth that triggers the lottery (so-called normal symbol time saving state, for example, a variable member is attached to the starting mouth) In this case, the open period of the variable member is long, the open probability of the variable member is high, the notification time of the open result of the variable member is short), and the like. Further, the "main variation display mode" is a variation mode relating to the main game symbol determined by referring to the main game table 3 and the like, and in this example, the variation mode determined by the process of step 1410-4. Has become. The "probability variation game state" is also called high probability, probability variation, or probability variation. The "auxiliary gaming state" is also called a time saving gaming state, a time saving gaming state, or a high base. The "first decorative pattern" is a decorative pattern displayed so that the player can easily recognize it. The effect of the first decorative symbol is that (1) it is possible to improve the attractiveness of the effect that is changing, (2) it is possible to notify the result of the game by displaying the fixed stop. The “second decorative symbol” is a decorative symbol that is changing at all times or when the player cannot easily see the first decorative symbol or when the player cannot see the first decorative symbol. The effect of the second decorative symbol is that (1) the result of the game can be notified by displaying the fixed stop display, (2) the fact that the game is changing can be notified, and the like. "Reach" is also called a reach state, reach display, and tempai, and it means a state where two identical decorative patterns are arranged. Mainly, the same decorative pattern is arranged in the left design row and the right design row. It is used when The “development effect” is an effect that is also referred to as a reach effect, a super reach (SP reach), a super reach effect (SP reach effect), or the like, and indicates a hit expectation degree of the fluctuation that occurs after the reach. The “draft” refers to display contents that enhance the interest of the game, and includes, for example, fluctuations in the identification information, stoppages, advance notices, moving images such as animation and live action, still images such as pictures, photographs, characters, or these A combination can be mentioned. The "stage (production stage)" is also called a mode (production mode), a zone (production zone), and a background production, and is a production mode indicated by a background image. The effect of the stage (production stage) is that (1) a display (first decorative pattern, notice, etc.) corresponding to the stage can be performed, and (2) expectation per hit can be suggested. “Temporary stop (temporary stop display)” means that the decoration pattern starts to change, and the decoration pattern appears to be fixedly stopped, but in reality, the decoration pattern is slightly moving (referred to as shaking fluctuation). Sometimes it is). The effect of the temporary stop (temporary stop display) can be shown as (1) a plurality of times of fluctuations are executed, (2) whether or not the fixed stop is performed (in other words, re-change without the fixed stop. Whether it is a hit without a fixed stop, or a different decorative pattern is changed without a fixed stop, etc.), and so on.

The following embodiment is a model in which two conventional type 1 pachinko gaming machines are mixed (type 1 type 1 multifunction machine). However, the present invention is not limited to this, and it is also within the range when applied to other gaming machines (for example, conventional first-class, second-class, third-class, pachinko gaming machines such as general electric officers). .. Note that the present embodiment is merely an example, and the locations and functions of each means, the order of each step regarding various processes, the timing of turning flags on and off, the name of the means that performs the processing of each step, and the like, It is not limited to the following modes. Further, the above-described embodiments and modified examples should not be limitedly understood to be applied to specific ones, and may be any combination. For example, it should be understood that a modification to one embodiment is a modification to another embodiment, and that one modification and another modification may be described independently. It should be understood that a combination of the modification and the other modification is also described. Further, in the present embodiment, a lottery table and a reference table exist for various tables, but these are not limited, and the lottery table may be used as the reference table or vice versa. Further, in the present example, the term “table” is not limited to that format, and one or more selection candidates may be selected from among a plurality of selection candidates based on one or more information. It should be understood that it is a mode that is associated. Furthermore, a numerical value as a specific example shown in the following embodiments and modifications (for example, winning probability at the time of lottery execution, maximum number of rounds at special game, symbol variation time, number of continuations in each game state, etc.) is This is just an example, and in particular, different conditions (for example, by the condition of the first main game side and the second main game side, by the condition of the probability variation game and the non-probability change game, and by the time reduction game) It is understood that the magnitude relations and combinations of the numerical values shown in (in terms of conditions such as the time-saving game, etc.) may be appropriately changed without departing from the spirit of the following embodiments and modifications. Should. For example, between the first main game side and the second main game side, the relationship between the winning probability at the time of executing the lottery and the expected value of the maximum number of rounds at the time of the special game is the first main game side=the second main game side. Even if it is illustrated as such, the size relationship may be changed appropriately such that the first main game side<the second main game side or the first main game side>the second main game side. Good (same for other values and conditions). Also, for example, when configuring as the number of continuation of the probability variation game state based on the meaning that it continues until the next big hit occurs, is "65535" set as the number of continuation (configured to substantially continue), Alternatively, the probability variation game state is maintained until the next big hit occurs without setting the number of times of continuation, even in the choice of the realization method based on the same purpose, as long as it does not largely deviate from the purpose of the following embodiment or modified example. Should be understood to be appropriately changed.

Here, the features (outline) of the pachinko gaming machine according to the present embodiment will be described before describing each component. Hereinafter, each element will be described in detail with reference to the drawings.

First, the basic structure of the front side of the pachinko gaming machine according to the present embodiment will be described with reference to FIG. Pachinko game machines are mainly composed of a game machine frame and a game board. Hereinafter, these will be described in order.

First, the gaming machine frame of the Pachinko gaming machine includes an outer frame D12, a front frame D14, a transparent plate D16, a door D18 (sometimes referred to as a door unit D18, a glass door D18), an upper ball plate D20, a lower ball plate D22 and Includes a firing handle D44. First, the outer frame D12 is a frame body for fixing the pachinko game machine at a position where it should be installed. The front frame D14 is a frame body that is aligned with the opening portion of the outer frame D12, and is attached to the outer frame D12 so as to be openable and closable via a hinge mechanism (not shown). The front frame D14 includes a mechanism for firing a game ball, a mechanism for detachably housing the game board, a mechanism for guiding or collecting the game ball, and the like. The transparent plate D16 is made of glass or the like and is supported by the door D18. The door D18 is openably and closably attached to the front frame D14 via a hinge mechanism (not shown). The upper ball dish D20 has a mechanism for storing the game balls, sending the game balls to the launch rail, and withdrawing the game balls to the lower ball dish D22. The lower ball plate D22 has a mechanism for storing and extracting game balls. In addition, a speaker D24 is provided between the upper bowl D20 and the lower bowl D22, and a sound effect according to a game state or the like is output.

Next, the game board has a game area D30 defined by an outer rail D32 and an inner rail D34. Then, in the game area D30, a mechanism such as a plurality of game nails and a windmill (not shown) and various general winning openings, a first main game starting opening (A10, A10-2), a second main game starting opening B10, Auxiliary game start opening H10, auxiliary game electric auditors product E10, first non-electric auditors product HD-1, second non-electrical auditors product HD-2, first big winning opening C10, second big winning opening C20, first main Game symbol display device A20, second main game symbol display device B20, effect display device SG, auxiliary game symbol display device H20, center decoration D38 (not shown) and outlet (D36, D36-2), general winning opening P10. Is installed. Hereinafter, each element will be described in detail in order.

Next, the first main game starting ports A10 and A10-2 are installed as start winning holes corresponding to the first main game. As a specific configuration, the first main game starting mouth A10 includes a first main game starting mouth entrance detecting device A11s, and the first main game starting mouth A10-2 is a first main game starting entrance detecting device. A11s-2 (not shown) is provided. Here, the first main game starting entrance ball detection device A11s is a sensor that detects the entrance of the game ball into the first main game starting opening A10, and the first main game starting entrance detection device A11s-2. Is a sensor that detects the entry of a game ball into the first main game starting opening A10-2, and generates the first main game starting opening entry information indicating the entry when entering the ball. The first main game starting opening A10-2 is provided as a first non-electric accessory HD-1 and an auxiliary game electric accessory E10 (specific entrance for opening the first non-electric accessory HD-1). When a game ball enters the first open entrance N1 in the distribution entrance C20), the first non-electric accessory HD-1 is closed by a mechanical actuation mechanism (not shown). It becomes an open state, and the game ball can enter the first main game starting opening A10-2. The first non-electric accessory HD-1 is physically closed by the weight of the entered game balls and the like when a predetermined number (for example, two balls) of game balls enter after the open state. The first non-electrical accessory HD-1 and the second main game starting opening HD-2 described later are so-called second type non-electrical accessories (also called mecha-chu, etc.), and the game balls won in other winning openings. Mechanically opened by the action, closed state by entering the game ball to the winning opening (here, the first main game starting opening A10-2 and the second main game starting opening B10) related to the second type non-electric accessory This is the configuration.

Next, the second main game starting port B10 is installed as a starting winning port corresponding to the second main game. As a specific configuration, the second main game starting mouth B10 includes a second main game starting mouth entrance detection device B11s. Here, the second main game starting opening ball entrance detection device B11s is a sensor that detects the entrance of a game ball into the second main game starting opening B10, and the second main game start that indicates the entrance of the game ball. Generates mouth entrance information. The second main game starting opening B10 is provided as the second non-electrical accessory HD-2, and the second opening entry ball in the auxiliary game electric accessory E10 for opening the second non-electrical accessory HD-2. When a game ball enters the mouth N2, the second non-electric accessory HD-2 is changed from the closed state to the open state by a mechanical actuation mechanism (not shown), and the game ball enters the second main game starting opening B10. Sphere becomes possible. The second main game non-electrical accessory HD-2 is physically closed by the weight of the game balls that have entered when a predetermined number of game balls (for example, two balls) have entered after being opened.

Next, the auxiliary game starting port H10 is equipped with an auxiliary game starting port entrance detection device H11s. Here, the auxiliary game start entrance ball detection device H11s is a sensor that detects the entrance of the game ball into the auxiliary game start entrance H10, and generates the auxiliary game start entrance ball information that indicates the entrance of the game ball. To do. The entry of the game ball into the auxiliary game starting opening H10 is an opportunity for a lottery to open the auxiliary game electric auditors' product E10.

Next, the auxiliary game electric role object E10 includes an auxiliary game electric role object entrance detection device E10s. Further, the auxiliary game electric accessory E10 includes a distribution device FS, a first opening entrance N1 and a second opening entrance N2. The game ball that has entered the auxiliary game electric accessory E10 is distributed by the distribution member FB of the distribution device FS so as to enter either the first opening entrance N1 or the second opening entrance N2. As described above, the first opening entrance N1 is an entrance for changing the first non-electric accessory HD-1 from the closed state to the opening state, and the second opening entrance N2 is It is an entrance for changing the second non-electric accessory HD-2 from the closed state to the open state.

Next, the first big winning opening C10 and the second big winning opening C20 are provided on the upper right of the outlet D36, and the game ball flowing down the right side of the game area D30 (based on the center of the game area) Before reaching the outlet D36, it is configured so as to easily pass through the area where the first special winning opening C10 and the second special winning opening C20 are arranged.

Next, the first big winning opening C10, when the first main game symbol (first special symbol) or the second main game symbol (second special symbol) is a big hit symbol, it is in an open state and has a horizontal rectangular shape. It is a winning opening corresponding to the main game, which is located on the upper right of the formed out opening D36. As a specific configuration, the first special winning opening C10 is a first special winning opening winning detection device C11s for detecting the entry of a game ball, and a first special winning opening electric prize C11d (and the first special winning prize). Mouth electric accessory solenoid C13). Here, the first special winning opening winning detection device C11s is a sensor that detects the entry of a game ball into the first special winning opening C10, and the first big winning opening entry information indicating the entry at the time of entering the ball. To generate. The first special winning opening electric accessory C11d changes the first special winning opening C10 to a normal state where the game ball cannot be won or difficult to win the first special winning opening C10 and an open state where the game ball is easy to win (the first (1) Special winning opening The electric accessory solenoid C13 is excited to be changed). Incidentally, in the present embodiment, the mode of the big winning opening is a lateral rectangular shape and is a mode in which the game ball can be changed between a normal state in which the game ball cannot be won or is difficult to win and an open state in which the game ball is easy to win. It is not limited to. In that case, for example, a mode in which a bar-shaped member provided in the special winning opening can be in an advanced state in which it is projected toward the player side and a retracted state in which it is retracted with respect to the player side (so-called, (Vero type attacker) or as a mode (so-called slide type attacker) in which the opening on the passage on which the game ball can roll can be used as a special winning opening and the opening can be closed or opened. Of course, it is suitable when it is desired to ensure that the number of balls entering the special winning opening is a predetermined number (for example, 10).

Next, the second special winning opening C20, which is in an open state when the second main game symbol (special symbol) is stopped by a small hit symbol, has a horizontal rectangular shape and is located above and to the right of the outlet D36. It is a winning hole corresponding to the main game. As a specific configuration, the second special winning opening C20 is a second special winning opening winning detection device C21s for detecting the entry of a game ball, and a second special winning opening electric prize C21d (and the second winning prize). Mouth electric accessory solenoid C23). Here, the second special winning opening winning detection device C21s is a sensor that detects the entry of a game ball into the second special winning opening C20, and the second big winning opening entry information indicating the entry when entering. To generate. And the game ball which entered into the second big winning opening C20 is configured to be detected by the second big winning opening winning detection device C21s. Next, the second special winning opening electric accessory C21d is configured such that the second special winning opening C20 is placed in the normal state where the game ball cannot be won or is difficult to win and the open state where the game ball is easy to win in the second special winning opening C20. Change. Incidentally, in the present embodiment, the mode of the big winning opening is a lateral rectangular shape and is a mode in which the game ball can be changed between a normal state in which the game ball cannot be won or is difficult to win and an open state in which the game ball is easy to win. It is not limited to. In that case, for example, a mode in which a bar-shaped member provided in the special winning opening can be in an advanced state in which it is projected to the player side and a retracted state in which it is retracted with respect to the player side (so-called, It may be a bello-type attacker) or a mode (so-called slide-type attacker) in which the opening on the passage on which the game ball can roll is used as a special winning opening, and the opening and closing of the opening can be adopted. This is suitable when it is desired to ensure that the number of balls entering the special winning opening is a predetermined number (for example, 10). Incidentally, the second big winning opening C20, even if the second main game symbol is stopped in other than the small hit symbol, for example, even if the second main game symbol is stopped in the big hit symbol, it may be configured to be open. Good.

Next, the first main game symbol display device A20 (second main game symbol display device B20) is related to the first main game symbol (second main game symbol) corresponding to the first main game (second main game). It is a device that executes the displayed information. As a specific configuration, the first main game symbol display device A20 (second main game symbol display device B20), the first main game symbol display portion A21g (second main game symbol display portion B21g), the first main game It is provided with a symbol holding display section A21h (second main game symbol holding display section B21h). Here, the first main game symbol reservation display portion A21h (second main game symbol reservation display portion B21h) is composed of four lamps, the number of lights of the lamp, the first main game (second main game) It corresponds to the number of reserves of the random number related to (the number of fluctuations of the main game symbol that is not executed). The first main game symbol display portion A21g (second main game symbol display portion B21g) is composed of, for example, a 7-segment LED, and the first main game symbol (second main game symbol) is "0" to "9". It is displayed with 10 types of numbers and "-" that is missing (however, it is not limited to this, and a 7-segment LED is used so that it becomes difficult for the player to recognize which main game symbol is displayed. It is preferable to use and display by a symbol or the like. Further, the number of holdings is not limited to the display of four lamps, and the maximum number of holdings of four lamps can be displayed (for example, one lamp is used. Number 1: lighting, hold number 2: slow blinking, hold number 3: medium speed blinking, hold number 4: high speed blinking).

Since the first main game symbol (second main game symbol) does not necessarily have a directing role, in the present embodiment, the first main game symbol display device A20 (second main game symbol display device B20). The size of is set so that it is inconspicuous. However, the first main design symbol (second main game symbol) itself has a directing role, and the first decorative symbol (consisting of a plurality of elements such as characters and numbers, also referred to as main decorative symbol) and the second. When adopting a method that does not display a decorative design (basically composed only of numbers, also called a sub-decorative design), a liquid crystal display such as the effect display device SG described later, the first main game design It may be configured to display (second main game symbol).

Next, the effect display device SG is a device that executes an effect image display including a decorative pattern that fluctuates/stops in conjunction with the first main game symbol/second main game symbol. Here, as a specific configuration, the effect display device SG includes a display area SG10 in which an effect is executed including variable display of decorative symbols and the like. Here, the display area SG10, the first hold display unit SG12 (and the second hold display unit SG13) that displays the main game hold information, and the change suggestion display unit that can suggest the jackpot expectation degree of the pattern change being executed. The SG 14 and, for example, a decorative symbol display area SG11 that displays a moving image of decorative symbol fluctuation in a plurality of columns simulating a game of a slot machine. Although the effect display device SG is composed of a liquid crystal display in the present embodiment, it may be composed of other display means such as a mechanical drum or an LED. Next, the 1st reservation display part SG12 (and the 2nd reservation display part SG13) is comprised from four lamps, and the said lamp is interlocked with the reservation lamp of the main game symbol.

Next, the auxiliary game symbol display device H20 is a device that executes a display related to the auxiliary game symbol. As a specific configuration, the auxiliary game symbol display device H20 includes an auxiliary game symbol display portion H21g and an auxiliary game symbol hold display portion H21h. Here, the auxiliary game symbol hold display unit H21h is composed of four lamps, and the number of lights of the lamp corresponds to the number of holding the auxiliary game symbol fluctuations (the number of auxiliary game symbol fluctuations not executed).

Next, the center decoration D38 is installed around the effect display device SG, is provided with a movable body accessory YK, and has functions such as a flow path for a game ball, protection of the effect display device SG, and decoration.

Next, the game effect lamp D26 is provided in the game region D30 or a region other than the game region D30, and plays a role by blinking or the like. The game effect lamp D26 is also provided in the center decoration, and plays a role by flashing or the like.

Next, the general winning opening P10 includes a general winning opening winning detection device C21s. When the general winning opening winning detection device C21s detects the entry of a game ball, a predetermined number of prize balls are played.

Next, the sub-input button SB is an operation member that is electrically connected to the sub-control board S and is operated (depressed) to execute an effect based on the operation. The operation modes of the sub input button SB include single-shot pressing (operation mode of pressing the sub input button SB only once in a short time), continuous hitting (operation mode of pressing the sub input button SB multiple times), and long pressing. (Operation mode in which the sub-input button SB is kept pressed for a predetermined period). The cross key SB-2 has four operation units, that is, upper, lower, left, and right, which are electrically connected to the sub-control board S. By operating the operation units, the choice of advance notice effect can be selected. It can be selected and the notice can be customized. In addition, the operation members that are operated (depressed) to execute the effect based on the operation are not limited to the sub input button SB and the cross key SB-2, and are electrically connected to the sub control board S. Further, it may be configured to have a lever for performing an effect (a movable body accessory is operated, etc.) by pulling it toward you, a stick for leaning forward, backward, leftward and rightward for inputting.

Next, with reference to FIG. 2, the basic structure on the back side of the pachinko gaming machine will be described. The pachinko gaming machine controls the overall operation of the pachinko gaming machine, and particularly controls overall gaming operations such as lottery when entering the first main game starting opening A10 (second main game starting opening B10) (that is, the game. A main control board M for performing control (which is directly related to a person's profit), a sub-main control unit SM for performing display control and the like relating to various effects on the effect display device SG that adds interest to the game content, and mainly A sub-sub control unit SS that executes an effect display, and a prize ball that pays out a game ball supplied from the prize ball tank KT to the upper bowl plate D20 according to a prize in the prize ball tank KT, the prize ball rail KR, and each prize hole. The prize ball payout device (set base) KE including the payout unit KE10, the prize ball payout control board KH for controlling the payout operation by the prize ball payout unit KE10, and the game ball (reserved ball) of the upper ball plate D20 as a game area. A launch control board D40 that controls the launching operation of a launcher D42 that launches one ball to D30, a power supply unit E that supplies power to each part of the pachinko gaming machine, and a switch that turns on/off the power of the pachinko gaming machine. Certain power switches Ea and the like are provided on the rear surface of the front frame D14 (on the side opposite to the game side).

Next, with reference to FIG. 3 and FIG. 4, the structure of the prize ball payout unit KE10 of the pachinko gaming machine and the operating principle for paying out the game balls according to the present embodiment will be described. First, as shown in the upper part of FIG. 3, the prize ball payout unit KE10 has a payout motor (sometimes referred to as a stepping motor) KE10m that is driven at the time of payout. As shown in the lower part of FIG. 3, the prize ball payout unit KE10 has a sprocket KE10p connected to a stepping motor KE10m. The prize ball payout unit KE10 having such a structure operates according to the following principle. First, when a game ball enters a winning opening in the game area, a winning signal is sent to the main control board M, the main control board M determines the number of payouts, and a prize ball signal is sent to the prize ball payout control board KH. To do. Alternatively, the game ball lending device such as the card unit R makes a request for ball lending to the prize ball payout control board KH. In response to this, the prize ball payout control board KH activates the prize ball payout unit KE10, and the stepping motor KE10m in the prize ball payout unit KE10 executes payout of the game balls. As shown in FIG. 4, as the stepping motor KE10m rotates, a sprocket KE10p (a member in which the first sprocket KE10p1, the second sprocket KE10p2, and the rotation confirmation member KE10p3 are integrated) is rotated, and the game ball is It is paid out one by one. The paid game balls are detected by a payout count sensor KE10s continuously provided downstream of the prize ball payout unit KE10. It should be noted that the cross section C-C shows a cross section along the flow path of the game ball (the flow path is easily visible) as shown in the drawing.

Further, the lower part of FIG. 3 is a diagram schematically showing a rotor position confirmation sensor (payout motor position sensor) KE10ms and a rotating body (sprocket) KE10p (one example). The rotor position confirmation sensor KE10ms is a photo sensor that has a pair of measuring units and detects an object between the measuring units by projecting and receiving light. Here, the pair of measurement units are a light projecting unit that projects light and a light receiving unit that receives light from the light projecting unit, and are arranged with the rotation confirmation member KE10p3 interposed therebetween. Here, the rotation confirmation member KE10p3 has six recesses formed along the circumference, and is turned off when the rotation confirmation member KE10p3 is interposed between the light projecting unit and the light receiving unit, When the rotation confirmation member KE10p3 is not interposed between the light projecting portion and the light receiving portion, it is turned on (state in the lower stage of FIG. 3).

Next, an electrical schematic configuration of the pachinko gaming machine according to the present embodiment will be described with reference to the block diagram of FIG. First, the pachinko gaming machine according to the present embodiment pays out game balls based on the main control board M that controls the progress of the game and information (signals, commands, etc.) from the main control board M, as described above. Based on the information (signals, commands, etc.) from the prize ball payout control board KH to be controlled and the main control board M, various effects on the effect display device SG such as the change/stop of the decorative pattern, the sound from the speaker D24, A sub-control board S (in this example, the sub-main control section SM and the sub-sub-control section SS are arranged on one board) that controls the lighting of the game effect lamp D26, the execution of error notification, etc., and these A power supply unit E for supplying power to the entire gaming machine including the control board is mainly configured, and various devices and apparatuses controlled by or input to the control board described above are game machines. Are provided at appropriate places.

The sub-control board S is a sub-main control unit SM that controls various effects on the effect display device SG such as variation/stop of the decorative pattern, sound from the speaker D24, lighting of the game effect lamp D26, and error notification. The display control device SG is provided with two control units of a sub-sub-control unit SS that executes display processing such as variable display/stop display of decorative symbols, and hold display and notice display.

Here, the main control board M, the prize-ball payout control board KH, the sub-main control section SM, and the sub-sub-control section SS have a CPU that performs various arithmetic processes, a ROM that stores a program that prescribes the arithmetic processes of the CPU, A RAM for temporarily storing data handled by the CPU (various data generated during a game, a computer program read from a ROM, etc.) is installed. Hereinafter, the schematic configuration of each substrate and the electrical connection mode between each substrate/device will be outlined.

First, the main control board M is an electric member of each first main game-related electric member, an electric member of each second main game-related electric member, an electric member of each first/second shared main game member, and each auxiliary game-related. The electric member is electrically connected to an electric member (input/output device) that is essential for the progress of the game, such as an electric member, and controls the progress of the game based on an input signal from each input device. The electric members of the main game related electric members and the auxiliary game related electric members will be described later. Further, the main control board M is also electrically connected to the prize ball payout control board KH and the sub control board S (sub-main control section SM/sub-sub control section SS), and based on the progress of the game, the prize ball payout. It is configured such that information (commands) related to etc. can be transmitted to the prize ball payout control board KH, and information (commands) related to the production/game progress state, etc. can be transmitted to the sub control board S. The main control board M can be connected to the hall computer HC or the like via an external connection terminal (not shown), and the main control board M is connected by wiring to the hall computer HC via the external connection terminal. Is configured to output game-related information from an external device.

Further, in the present embodiment, as shown by the arrows in FIG. 5, the main control board M and the prize ball payout control board KH are configured to be capable of bidirectional communication, while the main control board M and the sub-main board are arranged. The control unit SM is configured to enable one-way communication from the main control board M to the sub-main control unit SM (the communication method may be serial communication or parallel communication). The communication between the control boards (between the control devices) may be one-way communication or two-way communication.

Next, the prize ball payout control board KH is a prize ball payout device KE that executes payout of game balls, and a device that can be operated by the player and accepts a request for paying out the game balls to the prize ball payout control board KH. It is connected to the game ball lending device R that transmits and the launch control board D40 that controls the launch device (handle unit HU100, ball launch unit BU100, etc.). In this embodiment, the game ball lending device R is provided separately from the game machine, but it may be integrated with the game machine. In that case, the prize ball payout control board KH is used for lending. The control and management control of the recording medium for lending such as electronic money may be centralized.

Next, the sub-control board S is configured such that a performance display device SG for displaying a decorative design, a notice performance, etc., a speaker D24, a game effect lamp D26, and an execution mode of the performance are changed by operating the button performance. A sub-input button that is configured to change the settings of the gaming machine (details will be described later) by operating the customization in-execution screen, volume control screen, light intensity control screen, etc. It is connected to the SB and the cross key SB-2. In the present embodiment, as described above, the sub-control board S has the sub-main control section SM and the sub-sub-control section SS, and the sub-main control section SM controls the sound output from the speaker D24 and the game effect ( Decoration) The lighting control of the lamp D26, the determination control of the display content displayed on the effect display device SG, and the display control of the effect based on the operation of the sub input button SB and the cross key SB-2 are performed, and the sub sub control unit SS The display control on the effect display device SG is performed. In addition, in the present embodiment, the sub-main control unit SM and the sub-sub-control unit SS are configured to be integrated on the sub-control board S, but the present invention is not limited to this (configured as a separate board. Although it may be possible, there is an advantage in that it is possible to reduce the situation in which noise is mixed in the wiring and the like by configuring it as an integrated unit). Further, the work sharing in both control units can be appropriately changed, for example, by executing the voice control by the sub-sub control unit SS (suitable when a voice control circuit is integrated with VDP is adopted). Further, an electronic value may be given as the award ball without giving a physical award ball. Here, the effect controlled by the sub-main control unit SM is the result of the game, including the variation of the first main game symbol and the variation of the second main game symbol and the variation of the decorative symbol in a time-synchronized manner. It relates to the display of only information that does not affect.

Next, the game-related electric members will be described. As shown in the figure, in the gaming machine according to the present embodiment, as a game-related electric member, a first main game-related electric member A, which is a game-related electric member on the first main game side, and a second main game side. Second main game-related electric member B that is a game-related electric member, and first and second main game-shared electric member C that is a game-related electric member shared by the first main game side and the second main game side. And has an auxiliary game-related electric member H that is a game-related electric member on the auxiliary game side. The main control board M has these first main game-related electric members A, second main game-related electric members B, first and second main game shared-related electric members C, and auxiliary game-related electric members H. It is electrically connected. The main control board M is a first main game-related electric member A, a second main game-related electric member B, a first/second main game shared-related electric member C, and an auxiliary game-related electric member H. Of various signals, or output from the first main game-related electric member A, the second main game-related electric member B, the first/second main game shared-related electric member C, or the auxiliary game-related electric member H. Various signals such as sensor signals are input to the main control board M. Hereinafter, these game-related electric members will be described in order.

First, the first main game-related electric member A is an electric member related to the first main game. For example, as an electric member of the first main game-related electric member A, a first main game symbol display device A20 capable of stop display and variable display of the first main game symbol, and entry into the first main game start opening A10. There is a first main game starting mouth entrance detecting device A11s (first main game starting entrance detecting device A11s-2) and the like. The main control board M outputs a control signal to the first main game symbol display device A20. Further, the detection signal output from the first main game starting mouth entrance detecting device A11s (first main game starting entrance detecting device A11s-2) is input to the main control board M.

Next, the second main game-related electric member B is an electric member related to the second main game. For example, as an electric member of the second main game-related electric member B, a second main game symbol display device B20 capable of stop display and variable display of the second main game symbol, and entry into the second main game start opening B10. There is a second main game starting entrance ball detection device B11s and the like capable of detecting the. The main control board M outputs a control signal to the second main game symbol display device B20. Further, the detection signal output from the second main game starting entrance ball detection device B11s is input to the main control board M.

Next, the first/second main game common electric member C is an electric member related to both the first main game and the second main game. For example, as the first and second main game shared electric members C, the first special winning opening C10 of the first winning opening electric auditors solenoid C13 (not shown), the second big winning opening C20 of the second winning prize There is a mouth electric accessory solenoid C23 (not shown) and the like. Further, as the first and second main game common electric members C, the first big winning opening winning detection device C11s which is a sensor for detecting the entry of the game ball into the first big winning opening C10, and the second big winning opening. There is also a second special winning opening winning detection device C21s which is a sensor for detecting the entry of a game ball into C20. The main control board M outputs a drive signal to the first special winning opening electric prize solenoid C13 or the second special winning opening electric prize solenoid C23. The sensor signals output from the first special winning opening winning detection device C11s and the second special winning opening winning detection device C21s are input to the main control board M.

Next, the auxiliary game-related electric member H is an electric member related to the auxiliary game. For example, as the auxiliary game-related electric member H, a solenoid (not shown) for driving the second main game starting port electric accessory B11d provided in the second main game starting port B10, and stop display and fluctuation of the auxiliary game symbol. There are an auxiliary game symbol display device H20 that can be displayed, an auxiliary game starting opening ball entrance detecting device H11s that can detect a ball entering the auxiliary game starting opening H10, and the like. The main control board M outputs a drive signal to a solenoid that drives the second main game starting opening electric accessory B11d, and outputs a control signal to the auxiliary game symbol display device H20. In addition, the detection signal output from the auxiliary game starting entrance ball detection device H11s is input to the main control board M.

The electric member of the first main game symbol display device A20, the electric member of the second main game symbol display device B20, and the electric member of the auxiliary game symbol display device H20 are connected to the main control board M so that information can be transmitted. .. Further, the electric members forming the effect display device SG are connected to the sub-main control section SM so as to be capable of transmitting information. That is, the first main game symbol display device A20, the second main game symbol display device B20 and the auxiliary game symbol display device H20 are controlled by the main control board M, the effect display device SG is controlled by the sub-main control section SM. Means that. It should be noted that another game peripheral device may be controlled via another control board controlled by one-way communication (one-way communication) with the main control board M.

Next, FIG. 6 is a main flowchart showing a flow of general processing performed by the main control board M. After the power of the game machine is turned on, the process of FIG. That is, after powering on the gaming machine and performing initial settings (not shown), in step 1001, the CPU MC of the main control board M determines whether or not the setting key switch provided on the main control board M is off. To judge. If Yes in step 1001, the process proceeds to step 1002. In the case of No in step 1001 (when the setting key switch is operated), the CPUMC of the main control board M executes the processing of step 1003 (setting change processing described later), and shifts to the processing of step 1004. .. In step 1002, the CPUMC of the main control board M confirms the input port of the RAM clear button (also referred to as a reset button, a RAM clear switch, a setting change button, etc.) provided on the prize ball payout control board KH. It is determined whether or not the RAM clear button has been operated, that is, whether or not the administrator of the game arcade intentionally performed an operation to clear the contents of the RAM. If Yes in step 1002, in step 1004, the CPU MC of the main control board M clears all the RAM contents on the main control board M side. Next, in step 1006, the CPU MC of the main control board M transmits RAM clear information (command) indicating that the RAM of the main control board M has been cleared to the sub-main control section SM side (transmission at that timing). Alternatively, the command may be set at the timing and transmitted in the control command transmitting process described later), and the process proceeds to step 1015. On the other hand, if No in step 1002, in step 1007, the CPU MC of the main control board M determines whether or not the information indicating that the power supply is normally shut off is not stored in the RAM. If Yes in step 1007, in step 1008, the CPUMC of the main control board M checks the contents of the RAM area in the main control board M (for example, the checksum recorded at the time of power interruption and the RAM area are stored. Compare with the amount of information). Next, in step 1010, the CPUMC of the main control board M determines whether or not the contents of the RAM are not normal based on the check result (whether or not the information at the time of power interruption is accurately backed up in the RAM). To do. If Yes in step 1010, that is, if the data backed up in the RAM is abnormal, the process proceeds to step 1004 (RAM clearing process described above). On the other hand, if No in step 1007, that is, if the information indicating that the power has been normally shut off is stored in the RAM, or if No in step 1010, that is, if the data backed up in the RAM is normal, in step 1012, The CPU MC of the main control board M acquires various information commands at the time of power interruption that are stored (backed up) in the RAM of the main control board M, and in step 1014, acquires the various information commands on the sub-main control unit SM side. (At the timing, a command may be set and transmitted by the control command transmission process described later), and the main control is performed at step 1014-1. CPUMC of the board M, the return setting of the solenoid (auxiliary game electric accessory E10, the special winning opening (eg, the first big winning opening C10, the second big winning opening C20) open or closed state before the power off In order to return, it is determined whether or not the solenoid actuation bit is on in the order of the electric accessory, the special winning opening, and if it is on, (the auxiliary game electric accessory E10/special opening is opened before the power is turned off. It is determined to be inside, and the solenoid operation flag is stored in the corresponding address (in order to open it again)}, and the process proceeds to step 1015. In step 1015, the CPUMC of the main control board M stores information indicating that the power is normally turned on in the RAM, and proceeds to the processing of step 1016. Next, at step 1016, the CPUMC of the main control board M triggers a timer interrupt (for example, a hardware interrupt every about 1.5 ms) related to the main processing on the main control board M side shown in FIG. 8B. However, in this example, the interrupt cycle is set to T) (as a result, (b) of FIG. 8 is executed when the execution scheduled interrupt timing is reached}, and the process of step 1018 Move to. After step 1018, the CPU MC of the main control board M repeatedly executes various random number update processing (for example, random number counter increment processing) until the next timer interrupt timing is reached.

In this example, the gaming machine has a plurality of set values, but the correspondence between the operation mode of the setting change button and the change in the set value of the gaming machine can be freely designed as appropriate. For example, when the number of set values is 6 (the set value is any of “1” to “6”) and the set value at power-on is “6”, the setting change button is operated once. , The setting value becomes "5", and the setting value becomes "3" when the setting change button is operated three times. The setting value is changed from "6" to "1" according to the number of times the setting change button is operated. It is also possible to have a configuration in which the set value is sequentially incremented from “1” to “6” in accordance with the number of times the setting change button is operated. Further, in this case, if the setting value is "1" and the setting change button is operated once, the setting value becomes "6". When the button is operated, the set value may be changed to the upper limit value. Similarly, the configuration is such that the set value is incremented according to the number of times the setting change button is operated, and when the setting change button is operated with the setting value being the upper limit value (“6” in this example), The set value may be changed to the lower limit value (“1” in this example). Alternatively, the set value may be sequentially changed by long pressing the operation button.

Note that the setting change button and the RAM clear button may be provided as separate operation members, or one operation member may serve both as the setting change button and the RAM clear button.

The number of set values can be freely designed, such as 2, 3, 4, 5, and 6, for example. The smaller the number of set values (for example, when the number of set values is 2 or 3), the interest of the game based on having a plurality of set values is improved and the configuration of the gaming machine is simplified. It becomes possible, and the more the number of set values is (for example, when the number of set values is 5 or 6), the more interesting the game can be made.

FIG. 7 is a flowchart showing the flow of the setting change process. When the setting change process is started, in step 1003-1, a command indicating that the setting change process has started is set and transmitted to the sub control board S. As a result, the sub-control board S can display "in the setting change mode" or the like on the effect display device. At the same time, it outputs to the external terminal board as an outer end signal (security signal). In step 1003-2, it is confirmed whether or not the set value (set value data) is within the normal range (“1” to “6”). If Yes, the process proceeds to step 1003-4. If No in step 1003-2, that is, if it is determined that the set value (set value data) is an abnormal value other than “1” to “6”, the minimum payout rate is set in step 1003-3. The value (setting value data) “1” is set, and the process proceeds to step 1003-4. In step 1003-4, a special symbol display device (a first main game symbol display device A20 or a second main game symbol display device B20) may be referred to in a display mode (for example, all lighting) indicating that the setting is being changed. ) LED is turned on, and at the same time, the current set value is displayed on the set value display device provided on the main control board M. Next, in step 1003-5, it is confirmed whether or not the setting change button is input. If No, the process proceeds to step 1003-11. If Yes in step 1003-5, the setting value data switched by the setting change button is acquired in step 1003-6, and the process proceeds to step 1003-7. In step 1003-7, it is confirmed whether or not the current set value (set value data) is not the maximum value. If Yes, the process proceeds to step 1003-9, and the set value (set value data) is set to 1. to add. If No in step 1003-7, that is, if it is determined that the set value (set value data) is the maximum "6", the minimum payout rate "1" is set in step 1003-8. At the same time, the process proceeds to step 1003-9 and 1 is added to the set value (set value data). Subsequently, in step 1003-10, the setting value data is updated, and in step 1003-11, it is confirmed whether or not the setting key signal has fallen. In step 1003-11, if there is no fall of the setting key signal, the process proceeds to step 1003-5 and the processes of step 1003-5 to step 1003-11 are performed until the fall of the setting key signal is confirmed. repeat. In the case of Yes in step 1003-11, that is, when it is determined that the setting key switch has returned to the state before the setting is changed, in step 1003-12, the LEDs of the special symbol display device are all turned off to change the setting. After clearing the display mode indicating that, in step 1003-13, a command indicating that the setting change processing has ended is set and transmitted to the sub-control board S. As a result, the sub-control board S hides the "during setting change mode" being displayed on the effect display device, and stops the output to the external terminal board. After the process of step 1003-13 is completed, the process proceeds to step 1004 of this process to execute the RAM clear. It should be noted that although "1" to "6" are used as the setting value data managed by the RAM throughout the entire processing, the processing may be performed by substituting the setting value data "0" to "5", respectively. .. By doing this, when the RAM clear occurs due to the RAM abnormality, the abnormality determination (No in step 1003-2) due to the value of the RAM that manages the set value data being set to "0" is avoided. You can If the set value data is managed by "0" to "5" (at this time, in the case of setting of 3 steps, it is managed by "0" to "2"), "0" is treated as the set value data. Therefore, it is not judged as abnormal. Furthermore, when some sort of lottery is performed using the set value data (for example, when different data is selected for each set value in the prefetch table or the like), there is an advantage that the offset process in the table selection can be easily performed. Specifically, when the set value data is managed by "1" to "6", when it is used as it is as offset data for table selection, it is necessary to perform processing such as decrementing the start address by 1. When managing the value data with “0” to “5”, the value as it is can be used as the offset data. Actually, when the set value data is displayed on the set value display device, 1 is added to the set value data to display as “1” to “6”.

In this example, in step 1003-2, it is determined whether or not the set value (set value data) is within a normal range, in other words, the set value (set value data) confirmation process is executed. However, as the execution timing of the confirmation process,
(1) Timing immediately after the power is turned on (2) Timing to enter a predetermined entrance (3) Timing to enter the main game starting opening (4) Timing to enter the auxiliary game starting opening (5) Grand prize Entry timing to the mouth (6) Main game symbol variation start timing (7) Timing immediately after the game state is switched (8) Timing immediately after the big hit starts (9) Timing immediately after the big hit end Execute at the above timing Good. The setting value (setting value data) confirmation processing may be executed only at any one of the above nine timings, or the setting value (setting value data) may be checked at a plurality of the above nine timings. The confirmation process may be executed. For example, since the checksum process is executed when the power is turned on, it is not necessary to provide a process for checking only the set value (set value data). It may be configured not to execute the confirmation process of (setting value data).

Next, FIG. 8 is a flowchart showing the flow of the timer interrupt process performed by the main control board M. The CPU MC of the main control board M executes the process of FIG. 9B based on the interrupt request generated when the scheduled interrupt timing is reached. That is, triggered by the arrival of the scheduled interrupt cycle T (for example, a hardware interrupt about every 1.5 ms), in step 1000-S, the CPUMC of the main control board M executes a setting key operation determination process described later. , And shifts to the processing of step 1000-1.

The setting key operation determination processing determines whether or not the setting key switch is operated (whether or not the setting key is input to the setting key insertion port, and whether the setting change key switch is in the ON state). It is a process of determining whether or not). In the setting key operation determination process in the timer interrupt process, when it is determined that the setting key switch is operated (that is, the setting key is inserted into the setting key insertion port, and the setting key is rotated in the predetermined direction). By doing so, when the key switch for changing the setting is in the ON state), the current setting value of the gaming machine is displayed on a predetermined display device (in this example, the setting value display device).

Next, in step 1000-1, the CPUMC of the main control board M executes an input process described later. Next, in step 1000-2, the CPUMC of the main control board M executes various random number updating processes described later. Next, in step 1000-3, the CPUMC of the main control board M executes an initial value updating type random number updating process described later. Next, in step 1000-4, the CPUMC of the main control board M executes an initial value random number updating process described later. Next, in step 1000-5, the CPUMC of the main control board M executes a timer subtraction process described later. Next, in step 1000-6, the CPUMC of the main control board M executes a starting port 2 valid period setting process (a process of setting the valid period of the second main game starting port B10) described later. Next, in step 1000-7, the CPUMC of the main control board M executes a prize monitoring process described later. Next, in step 3000, the CPUMC of the main control board M executes a prize ball payout command transmission control process described later. In addition, the number of prize balls to be paid out when a game ball is won at each winning opening is three balls for the first main game starting opening A10, one ball for the first main game starting opening A10-2, and a second main game starting opening B10. 1 ball, auxiliary game electric accessory E10 (sorting ball entrance C20) 1 ball, 1st big winning opening C10 15 balls, 2nd big winning opening C20 5 balls, left general winning opening (general winning opening P10 has 10 balls and the right general winning opening P20 (not shown in FIG. 1 etc.) has 10 balls. The number of payouts of these prize balls is an example, and the number of payouts of the prize balls is the same or different when the first main game starting opening A10 is entered and when the second main game starting opening B10 is entered. Alternatively, the number of payouts of the prize balls may be the same or different when the player enters the first special winning opening C10 and when the player enters the second special winning opening C20. However, the number of prize balls of all the winning openings provided in the pachinko gaming machine according to the present example does not exceed 15 for one prize (ball) and is constant (abnormal) regardless of the gaming state. It is configured so that it is invalidated under circumstances or while an error is occurring), and it is configured so that prize balls are not paid out except for winning, while realizing various game states. The direct game result is summarized in "whether or not the fired game ball wins a predetermined winning opening".

In this example, since the specific prize-ball payout control process is performed not by the main control board M but by the prize-ball payout control board KH, the main control board M manages the progress of the payout control in real time. However, when there is a failure due to a sudden matter such as a power failure while paying out the prize for one game ball, there is a case where the correct number of prize balls cannot be performed. Therefore, in this example, a retry function at the time of abnormality for paying out the game ball for the prize again (for example, when the game ball wins the first main game starting opening A10 and one game ball is paid out). In this case, the power is cut off, and after that, after the power is restored, the remaining three game balls are paid out. Of course, by providing a backup function to the prize ball payout control board KH, it is possible to realize the correct number of prize ball payouts even if such an abnormality occurs. The function may not be provided.

Next, in step 2000, the CPUMC of the main control board M executes a ball entrance detection process described later. Next, in step 1100, the CPUMC of the main control board M executes a later-described auxiliary game content determination random number acquisition process. Next, in step 1200, the CPUMC of the main control board M executes an electric accessory driving determination process, which will be described later. Next, in step 1250, the CPUMC of the main control board M executes a distribution member drive control process described later. Next, in step 1280, the CPUMC of the main control board M executes a first non-electric auditors product drive control process described later. Next, in step 1290, the CPUMC of the main control board M executes a second non-electric auditors product drive control process described later. Next, in step 1300, the CPUMC of the main control board M executes a main game content determination random number acquisition process described later. Next, in step 1400, the CPU MC of the main control board M executes a main game symbol display process described later. Next, in step 1700, the CPU MC of the main control board M executes a small hitting game symbol control process described later. Next, in step 1600, the CPUMC of the main control board M executes a special game control process described later. Next, in step 1601, the CPUMC of the main control board M executes a special winning opening valid period setting process. Next, in step 1550, the CPUMC of the main control board M executes a special game operating condition determination process described later. Next, in step 1550-1, the CPUMC of the main control board M executes an abnormality detection process. Next, in step 1550-2, the CPUMC of the main control board M executes a ball entry time abnormality detection process. Next, in step 1550-3, the CPUMC of the main control board M executes a game state display process. Next, in step 1550-4, the CPUMC of the main control board M executes a handle state signal inspection process. Next, in step 1550-5, the CPUMC of the main control board M executes an outlet monitoring process. Next, in step 1550-6, the CPUMC of the main control board M executes an LED output process. Next, in step 1900, the CPUMC of the main control board M executes a fraud detection information management process described later. Next, in step 1950, the CPUMC of the main control board M executes an error management process described later. Next, in step 1550-7, the CPUMC of the main control board M executes a firing control signal output process described later. Next, in step 1550-8, the CPUMC of the main control board M executes a test signal output process. Next, in step 1550-9, the CPUMC of the main control board M executes a solenoid output process. Next, in step 1999, the CPUMC of the main control board M executes a control command transmission process (transmits the command set in each process described above to the sub-main control unit side). Next, in step 3500, the CPUMC of the main control board M executes an external signal output process described later. Next, in step 1550-11, the CPUMC of the main control board M sets to permit the generation of a timer interrupt, and returns to the processing that was being executed immediately before the execution of this interrupt processing.

The input process is a process of determining a signal input to the main control board M from an input device such as a sensor and setting a flag or the like corresponding to the signal, and in this example, it is attached to the game board surface. Switch (for example, the first main game start entrance ball detection device A11s, A11s-2, the second main game start entrance ball detection device B11s, auxiliary game start entrance ball detection device H11s, the first big winning opening prize detection device C11s, second big winning opening winning detecting device C21s, general winning detecting device, auxiliary game electric auditors' object entrance detecting device E10s, etc.), first opening winning entrance for detecting entrance into first opening entrance N1 Ball entrance sensor, second open entrance entrance sensor for detecting entrance into the second open entrance N2, out ball count switch for detecting entrance into the out entrance (D36, D36-2), disconnection Short circuit power supply abnormality detection signal, open signal (for example, front frame D14, door D18, etc.), magnetic detection signal 1 (detection signal by magnetic detection sensor 1), radio wave detection signal, shock detection signal, touch state signal, and magnetic detection signal 2 This is a process of monitoring the input of (a detection signal from the magnetic detection sensor 2). In this example, with respect to a special input such as a RAM clear switch, the input determination is performed by a process different from the input process.

The various random number update process is a process of relatively simply updating the random number used for the lottery that has an extremely low effect on the payout (for example, adding a constant), and in the present example, a normal pattern variation pattern random number (for example, , Is a process of updating the auxiliary game symbol variation mode random number) and the variation pattern random number (for example, variation mode random number).

The initial value update type random number update process is a process of updating the random numbers used in the lottery in which the influence on the payout is to a certain extent (a process different from the various random number update process described above), and in this example, Random number per symbol (for example, auxiliary game symbol winning random number), normal symbol symbol random number (for example, auxiliary game symbol stop symbol random number), special symbol random number (for example, symbol lottery random number), update special symbol-per-random number, etc. This is a process for doing.

The initial value random number update process is a process of updating the random number for determining the initial value of the random number updated in the initial value update type random number update process used in the lottery in which the influence on the payout occurs to a certain extent. In the example, as an example of the random number to be updated, an initial value random number per normal symbol, a normal symbol initial value random number, a special symbol initial value random number, a special symbol per soft initial value random number and the like can be exemplified. In addition, the initial value random number per normal symbol and the normal symbol initial value random number are random numbers updated in the initial value random number updating process when configured to have a plurality of auxiliary game content determination random numbers.

The timer subtraction process is a process of updating a 2-byte timer (for example, a first/second main game symbol variation management timer, an electric accessory release timer, a special game timer, an open time timer, etc.).

The starting opening 2 effective period setting process is a winning opening (for example, the second main This is a process of setting the valid period of the game starting opening B10).

The winning monitoring process is a process of updating the passage counter of the switch, creating a security output request to be output to the external terminal board, and sending a command to be sent to the effect control board.

The special winning opening valid period setting process is a process of storing the result of determination of the valid period of the special winning opening (for example, the first special winning opening C10, the second special winning opening C20). When the special winning opening C22 has a specific area C22, the result of determination of the valid period of the specific area C22 may be stored by the special winning opening valid period setting process.

The abnormality detection process is a process of monitoring magnetism, disconnection/short circuit, power supply, radio wave, glass frame set/open/closed state of frame of game board D35, shock, and the like.

With the ball passing time abnormality detection process, in order to detect the ball passing time abnormality when the game ball enters the various ball inlets (for example, the first main game starting port A10), each switch level is continuous. This is a process of monitoring the on-time (continuous on-time of the ball entrance sensor).

The game state display processing is the number of times the special electric auditors continuously operate (the number of execution rounds in the big hit), the error state, the number of operation-holding balls of the normal symbol display device (currently displayed on the auxiliary game symbol display device H20). Of the auxiliary game holding ball) and the special symbol display device operation holding ball number (current main game holding ball number displayed on the first main game symbol display device A20 or the second main game symbol display device B20) display request Is a process for performing.

The handle state signal inspection process is a process of monitoring the touch state of the firing handle (for example, the firing handle D44).

The out-port monitoring process is a process of monitoring the out-port (for example, the out-port D36) in order to create a security output request.

LED output processing, the display in the special symbol display device (for example, the display of the first main game symbol in the first main game symbol display device A20, the display of the second main game symbol in the second main game symbol display device B20, the second 1 main game symbol display device A20 display of the first main game side operation reserve ball number, the second main game symbol display device B20 second main game side operation reserve ball number display), display in the normal symbol display device (Display of the auxiliary symbol in the auxiliary game symbol display device H20, display of the operation reserve ball number of the auxiliary game side in the auxiliary game symbol display device H20), error state display, game state display, separate display (for example, right Initialization and display of the display to indicate the situation that should be hit, the situation that left-handed should be left) and the number of times the special electric auditors operate continuously (display of the number of rounds in a big hit). This is a process of sequentially performing control of LED output such as data output controlled by the main control board M side.

The launch control signal output process is a process of outputting a signal for prohibiting or permitting the launch of a game ball, which will be described in detail later.

The test signal output process is a process of creating a signal to be output to a test device outside the gaming machine and outputting the signal to a corresponding output port.

The solenoid output process is to output the output data of the ordinary electric winning combination (for example, the auxiliary gaming electric winning combination E10) solenoid and the special winning opening (for example, the first big winning opening C10 and the second big winning opening C20) solenoid. Processing.

Next, FIG. 9 is a main flowchart showing a flow of the NMI interrupt processing (when the power is cut off) performed by the main control board M. First, the NMI interrupt processing will be described. The power failure signal from the reset IC is configured to be input to the NMI terminal of the CPU of the main control board M, and the processing of FIG. That is, when the gaming machine is powered off (in this example, when an NMI interrupt occurs), in step 1019-1, the CPU MC of the main control board M determines whether or not a timer interrupt is in progress. If Yes in step 1019-1, the CPUMC of the main control board M determines in step 1019-2 whether or not the information indicating that the power is normally turned on is stored in the RAM. On the other hand, if No in step 1019-1, the process of step 1019-1 is performed again. If Yes in step 1019-2, in step 1019-3, the CPU MC of the main control board M stores information indicating that the power supply is abnormally cut in the RAM, and proceeds to the next step 1022. On the other hand, in the case of No in step 1019-2, the CPUMC of the main control board M stores the information indicating that the power supply is normally shut off in the RAM in step 1019-4, and in step 1020, the CPU MC of the main control board M. The CPUMC sets power interruption information (for example, checksum) based on the information in the RAM area. Next, in step 1022, the CPUMC of the main control board M prohibits writing to the RAM area, prohibits timer interrupt processing, and shifts to power-off waiting loop processing. The example in which the power interruption process (FIG. 9) is executed by inputting the power interruption signal to the NMI terminal of the CPU has been described, but the invention is not limited to this, and the power interruption signal may be input to a specific input port. It is also possible to set and set the main control board side main process (FIG. 6) or the timer interrupt process (FIG. 8) to monitor the specific input port to determine the power interruption and perform the power interruption processing. Note that power interruption may be referred to as power interruption, and power interruption processing may be referred to as power interruption processing, power interruption processing, and electricity interruption processing.

Next, FIG. 10 is a flowchart of the prize-ball payout command transmission control process according to the subroutine of step 3000 in FIG. First, in step 3100, the main control board M executes a payout control board transmission control process described later. Next, in step 3200, the main control board M executes an anti-payout control board reception control processing, which will be described later, and shifts to the next processing (processing in step 2000).

Next, FIG. 11 shows a flowchart of the payout control board transmission control process according to the subroutine of step 3100 of FIG. First, in step 3105, the CPU MC of the main control board M determines whether or not the payout signal is OFF, that is, whether or not the payout is currently executed. If Yes in step 3105, in step 3110, the CPUMC of the main control board M determines whether or not there is an unpaid prize ball (a prize ball that has not yet transmitted the prize ball payout command to the prize ball payout control board KH side). Determine whether. In the case of Yes in step 3110, in step 3115, the CPUMC of the main control board M is an error that is unsuitable for performing the prize ball payout related errors (for example, an error related to a failure of the payout motor, an upper plate full tank). , Out-of-ball error, etc.) has not occurred. In the case of Yes in step 3115, in step 3120, the CPUMC of the main control substrate M has a prize ball payout command for the number of prize ball payouts corresponding to the unpaid prize ball information in the order in which the payout process is executed this time (see FIG. 12). ) Is set. Then, in step 3125, the CPUMC of the main control board M erases the unpaid prize ball information corresponding to the award ball payout command set this time, and executes a process of shifting the information thereafter. Next, in step 3130, the CPUMC of the main control board M transmits the set prize ball payout command to the prize ball payout control board KH side, and shifts to the next processing (antipayment control board reception control processing of step 3200). To do. In addition, also in the case of No in step 3105, step 3110 and step 3115, the process shifts to the next process (process of step 3200).

Next, FIG. 13 shows a flow chart of the payout control board reception control processing according to the subroutine of step 3200 of FIG. First, in step 3205, the CPUMC of the main control board M determines whether or not the payout related information is received. Here, if Yes in step 3205, in step 3210, the CPUMC of the main control board M includes error information (ball out error, upper plate full tank error, other payout related error) in the received payout related information. Or not. In the case of Yes in step 3210, in step 3215, the CPUMC of the main control board M turns on the error flag related to the corresponding error, and thereby sets the error information on the prize ball payout control board KH side to the main control board M side. But manage (unified management). On the other hand, in the case of No in step 3210, in step 3220, the CPU MC of the main control board M turns off the error flag related to the error on the prize ball payout control board KH side. Then, in step 3225, the CPUMC of the main control board M determines whether or not the prize-ball payout completion information is present in the received payout-related information. In the case of Yes in step 3225, in step 3230, the CPUMC of the main control board M clears the set prize ball payout command (the prize ball payout command related to the present payout completion), and performs the next process (step 2000). Process). Even if No in step 3205 and step 3225, the process proceeds to the next process (process in step 2000).

Next, FIG. 14 is a flow chart of the incoming ball detection process according to the subroutine of step 2000 in FIG. First, in step 2100, the CPU MC of the main control board M executes an auxiliary game electric auditors object entrance detection process described later. Next, in step 2200, the CPU MC of the main control board M executes a main game starting opening detection process, which will be described later. Next, in step 2350, the CPUMC of the main control board M executes a first (second) special winning opening detection process, which will be described later. Next, in step 2400, the CPUMC of the main control board M executes a general winning opening detection processing, which will be described later. Next, in step 2500, the CPUMC of the main control board M executes a discharge ball detection process described later. Next, in step 2600, the CPUMC of the main control board M executes an out-port entrance detecting process, which will be described later. Next, in step 2700, the CPUMC of the main control board M executes a prize ball determination process, which will be described later, and shifts to the next process (the process of step 1100).

Next, FIG. 15 is a flowchart of the auxiliary game starting opening entrance detection process according to the subroutine of step 2100 in FIG. First, in step 2102, the CPU MC of the main control board M determines whether or not the auxiliary game starting opening detection continuation flag is off. In the case of Yes in step 2102, in step 2104, the CPUMC of the main control board M receives the input from the auxiliary game starting mouth entrance detecting device H11s as the entrance detecting time (above that time, the auxiliary game starting entrance detecting device H11s. When the input is detected, it is determined whether or not it is ON for a time longer than the time when it is considered that the auxiliary game starting opening H10 has entered the ball. If Yes in step 2104, in step 2106, the CPU MC of the main control board M turns on the auxiliary game start flag. Next, in step 2108, the CPU MC of the main control board M turns on the auxiliary game starting opening detection continuation flag, and shifts to the next processing (processing of step 2150).

On the other hand, in the case of No in step 2102, in step 2110, the CPUMC of the main control board M detects the detection end time of the input from the auxiliary game starting entrance ball detection device H11s (the auxiliary game starting entrance ball detection device or more). When H11s does not detect the input, it is determined whether or not the game ball is OFF for more than the time it is considered that the game ball has completed passing through the auxiliary game starting entrance ball detection device H11s). If Yes in step 2110, in step 2112, the CPU MC of the main control board M turns off the auxiliary game starting opening detection continuation flag, and proceeds to the next process (process of step 2150). Even if No in step 2104 or step 2110, the process proceeds to the next process (process in step 2150).

Next, FIG. 16 and FIG. 17 are flowcharts of the main game starting opening entrance detection process according to the subroutine of step 2200 in FIG. First, in step 2202, the CPU MC of the main control board M determines whether or not the first main game starting opening (first main game starting opening A10) detection continuation flag is off. If Yes in step 2202, in step 2204, the CPU MC of the main control board M receives the input from the first main game starting mouth entrance detection device A11s as the entrance detection time (above that time, the first main game starting entrance). When the ball detection device A11s detects an input, it is determined whether or not it is ON for more than the time when it is considered that there is a ball in the first main game starting opening A10). If Yes in step 2204, in step 2206, the CPU MC of the main control board M turns on the first main game start flag. Next, in step 2208, the CPUMC of the main control board M adds (increments) 1 to the incoming ball number counter value. Next, in step 2210, the CPUMC of the main control board M turns on the first main game starting opening detection continuation flag. Next, in step 2211, the CPUMC of the main control board M adds (increments) 1 to the counter value of the starting entrance ball number counter, and proceeds to step 2216.

On the other hand, in the case of No in step 2202, in step 2212, the CPUMC of the main control board M detects the input time from the incoming ball number counter (the first main game starting mouth incoming ball detection device A11s receives the input for the detection time or more). If not detected, it is determined whether or not the game ball is OFF for more than the time it is considered that the game ball has passed the first main game start opening entrance detection device A11s). If Yes in step 2212, in step 2214, the CPU MC of the main control board M turns off the first main game starting opening detection continuation flag. Next, in step 2215, the CPU MC of the main control board M turns off the first main game starting opening long time detection flag, and proceeds to step 2216. Even if No in Steps 2204 and 2212, the process proceeds to Step 2216.

Next, in step 2216, the CPUMC of the main control board M determines whether or not the first main game starting opening confirmation sensor detects a game ball. If Yes in step 2216, in step 2218, the CPU MC of the main control board M adds (increments) 1 to the first main game starting opening confirmation counter value, and proceeds to step 2220. Even if No in step 2216, the process proceeds to step 2220.

Next, in step 2220, the CPUMC of the main control board M determines whether or not the first main game starting opening (A10-2) detection continuation flag is off. In the case of Yes in step 2220, in step 2224, the CPU MC of the main control board M determines that the input from the first main game starting opening (A10-2) entrance detecting device is the entrance detecting time (equal to or more than that time, the first main When the game start opening (A10-2) entrance detection device detects an input, it is determined whether or not it is ON for at least the time when it is considered that there is a entrance in the first main game start opening A10-2. If Yes in step 2224, in step 2226, the CPU MC of the main control board M turns on the first main game start flag. Next, in step 2228, the CPUMC of the main control board M adds (increments) 1 to the incoming ball number counter value. Next, in step 2230, the CPUMC of the main control board M turns on the first main game starting opening (A10-2) detection continuation flag. Next, in step 2231, the CPU MC of the main control board M adds (increments) 1 to the counter value of the starting entrance ball number counter, and proceeds to step 2242.

On the other hand, in the case of No in step 2220, in step 2232, the CPUMC of the main control board M detects the input time from the incoming ball number counter (above that time, the first main game starting opening (A10-2) incoming ball detection). When the device does not detect the input, it is determined whether or not the game ball is OFF for the first main game starting opening (A10-2), which is regarded as having completed passing through the entrance detecting device). If Yes in step 2232, in step 2234, the CPU MC of the main control board M turns off the first main game starting opening (A10-2) detection continuation flag. Next, in step 2235, the CPU MC of the main control board M turns off the first main game starting opening (A10-2) long-time detection flag, and proceeds to step 2242. Even if No in Steps 2224 and 2232, the process moves to Step 2242.

Next, in step 2242, the CPU MC of the main control board M determines whether or not the second main game starting opening detection continuation flag is off. In the case of Yes in step 2242, in step 2244, the second main game starting mouth entrance determination unit determines that the input from the second main game starting entrance entrance detecting device B11s is the entrance detection time (above that time, the second main When the game starting opening entrance detecting device B11s detects an input, it is determined whether or not the ON state is equal to or more than a time when it is considered that there is a entering ball in the second main game starting opening B10). If Yes in step 2244, in step 2245, the CPU MC of the main control board M determines whether or not the flag during the second main game starting opening valid period is on. If Yes in step 2245, in step 2246, the CPU MC of the main control board M turns on the second main game start flag. Next, in step 2248, the CPUMC of the main control board M adds (increments) 1 to the incoming ball number counter value. Next, in step 2250, the CPUMC of the main control board M turns on the second main game starting opening detection continuation flag, and proceeds to step 2260.

On the other hand, in the case of No in step 2245 (when the ball entering the game ball is detected during the period in which the ball entering the second main game starting opening B10 is not effective), in step 2251 the CPUMC of the main control board M determines 2 It is determined that there is an illegal ball entry in the main game starting port B10, a second main game starting port illegal ball entering command (command to the sub-control board S side) is set, and the process proceeds to step 2260. Even if No in step 2244, the process proceeds to step 2260.

On the other hand, in the case of No in step 2242, in step 2252, the CPUMC of the main control board M detects that the input from the second main game starting entrance ball detection device B11s is the detection time (equal to or more than the second main game starting entrance). When the ball detection device B11s does not detect the input, it is determined whether or not the game ball is OFF for at least the time when it is considered that the game ball has passed the second main game starting opening ball detection device B11s). If Yes in step 2252, in step 2254, the CPU MC of the main control board M turns off the second main game starting opening detection continuation flag. Next, in step 2258, the CPUMC of the main control board M turns off the second main game starting opening long time detection flag, and proceeds to step 2260. Even if No in step 2252, the process proceeds to step 2260.

Next, in step 2260, the CPUMC of the main control board M determines that the first main game starting opening (A10, A10-2) entrance detecting device (second main game starting entrance entering detecting device B11s) has detected an illegal time ( It is a time that exceeds the time detected as a normal ball entry, and it is determined whether or not it is ON for more than the time when it is determined that fraud is performed. If Yes in step 2260, in step 2262, the CPU MC of the main control board M turns on the first (second) main game starting opening long time detection flag, and proceeds to the next process (process of step 2350). On the other hand, if No in step 2260, the process moves to the next process (process in step 2350).

Next, FIG. 18 is a flowchart of the first (second) special winning opening detection process according to the subroutine of step 2350 in FIG. First, in step 2352, the CPUMC of the main control board M determines whether or not the first (second) special winning opening detection continuation flag is off. If Yes in step 2352, in step 2354, the CPU MC of the main control board M determines that the input from the first special winning opening winning detection device C11s (the second special winning opening winning detection device C21s) is the detection time (the time concerned). As described above, when the entrance detecting device detects an input, it is determined whether or not it is ON for more than the time when it is considered that there is a entrance at the entrance. If Yes in step 2354, in step 2355, the CPUMC of the main control board M determines whether or not the flag during the first (second) special winning opening valid period is on. If Yes in step 2355, in step 2356, the CPUMC of the main control board M turns on the first (second) special winning opening ball flag. Next, at step 2358, 1 is added (incremented) to the incoming ball number counter value. Next, in step 2360, the CPUMC of the main control board M turns on the first (second) special winning opening detection continuation flag, and proceeds to step 2370.

On the other hand, in the case of No in step 2355 (when the entry of the game ball is detected while the entry into the special winning opening is not valid), in step 2361, the CPUMC of the main control board M is illegal in the special winning opening. It is determined that there is a special ball entry, a first (second) special winning opening illegal entry command (command to the sub-control board S side) is set, and the process proceeds to step 2370. Even if No in step 2354, the process proceeds to step 2370.

On the other hand, if No in step 2352, in step 2362, the CPUMC of the main control board M detects that the input from the first special winning opening winning detection device C11s (the second special winning opening winning detection device C21s) is the detection time (the time concerned). As described above, when the first big winning award winning detecting device C11s (the second big winning award winning detecting device C21s) does not detect the input, the game ball is the first big winning award winning detecting device C11s (the second big winning award winning device). It is determined whether or not it is OFF for more than the time when it is considered that the detection device C21s) has passed through}. If Yes in step 2362, in step 2364, the CPU MC of the main control board M turns off the first (second) special winning opening detection continuation flag. Next, in step 2368, the CPUMC of the main control board M turns off the first (second) special winning opening long time detection flag, and proceeds to step 2370. On the other hand, if No in step 2362, the process moves to step 2370.

Next, in step 2370, the CPUMC of the main control board M determines that an input from the first special winning opening winning detection device C11s (the second special winning opening winning detection device C21s) is a fraudulent detection time (above that time, the first large Time when it is considered that an illegal ball is detected in the first special winning opening C10 (the second special winning opening C20) when the winning opening winning detection device C11s (the second special winning opening detection device C21s) detects the input. } It is determined whether or not the above is ON. If Yes in step 2370, in step 2372, the CPU MC of the main control board M turns on the first (second) special winning opening long time detection flag, and proceeds to the next process (process of step 2400). On the other hand, if No in step 2370, the next process (process in step 2400) is performed.

Next, FIG. 19 is a flowchart of the general winning opening detection process according to the subroutine of step 2400 in FIG. In addition, a general winning opening (the left general winning opening P10 and the right general winning opening P20 may be generically referred to as a general winning opening) is paid out by the game ball entering, but the game ball is paid out. The general winning opening entrance detecting device P11s (in the present embodiment, is a ball entrance that does not affect the progress of the game (does not execute the lottery that affects the progress of the game) and is a sensor that detects the entrance of the game ball. General prize opening entrance detection device P11s which is a sensor for detecting the entrance of the game ball into the left general prize opening P10, and a general prize entrance entrance which is a sensor which detects the entrance of the game ball into the right general prize opening P20 It has two general winning a prize entrance detection devices P11s together with the detection device P11s.

First, in step 2402, the CPU MC of the main control board M determines whether or not the general winning opening detection continuation flag is off. If Yes in step 2402, in step 2404, the CPUMC of the main control board M detects that the input from the general winning a prize entrance detecting device is the detection time of the entrance (the general winning entrance detecting device detects the input. Then, it is determined whether or not it is ON for more than the time when it is considered that there is a ball in the general winning opening. If Yes in step 2404, in step 2406, the CPU MC of the main control board M turns on the general winning opening entry flag. Next, in step 2408, the CPUMC of the main control board M adds (increments) 1 to the incoming ball number counter value. Next, in step 2410, the CPU MC of the main control board M turns on the general winning opening detection continuation flag, and proceeds to step 2420. On the other hand, in the case of No in step 2402, in step 2412, the CPUMC of the main control board M determines that the input from the general winning award entrance detecting device is the entering detection time If is not detected, it is determined whether or not the game ball is OFF for more than the time it is considered that the game ball has passed through the general winning a prize entrance detecting device). If Yes in step 2412, in step 2414, the CPU MC of the main control board M turns off the general winning opening detection continuation flag. Next, in step 2418, the CPU MC of the main control board M turns off the general winning opening long-time detection flag, and proceeds to step 2420. Even if No in Steps 2404 and 2412, the process proceeds to Step 2420.

Next, in step 2420, the CPU MC of the main control board M determines that the input from the general winning award entrance detecting device is a fraudulent detection time {if the general winning award entrance detecting device detects the input, the general award winning prize is detected. It is determined whether or not it is ON for more than the time when it is considered that an illegal entrance into the mouth is detected}. If Yes in step 2420, in step 2422, the CPU MC of the main control board M turns on the general winning opening long-time detection flag, and proceeds to the next process (process of step 2500). Even if No in step 2420, the process proceeds to the next process (process in step 2500).

Next, FIG. 20 is a flowchart of the discharged ball detection process according to the subroutine of step 2500 in FIG. First, in step 2502, the CPUMC of the main control board M determines whether or not the discharge confirmation detection continuation flag is off. If Yes in step 2502, in step 2504, the CPUMC of the main control board M determines whether the input from the total discharge confirmation sensor C90s is the ball detection time (when the total discharge confirmation sensor C90s detects the input, the total discharge confirmation is performed). It is determined whether or not the sensor C90s is ON for more than the time it is considered that a ball has entered. If Yes in step 2504, in step 2506, the CPU MC of the main control board M turns on the discharge confirmation detection continuation flag. Next, in step 2508, the CPUMC of the main control board M adds (increments) 1 to the total discharge confirmation number counter, and proceeds to the next process (process of step 2520).

On the other hand, in the case of No in step 2502, in step 2510, the CPUMC of the main control board M detects the end time of the input from the total discharge confirmation sensor C90s (the total discharge confirmation sensor C90s did not detect the input for the above-mentioned time In this case, it is determined whether or not the game ball is OFF for more than the time it is considered that the total discharge confirmation sensor C90s has passed. If Yes in step 2510, in step 2512, the CPU MC of the main control board M turns off the discharge confirmation detection continuation flag. Next, in step 2514, the CPUMC of the main control board M turns off the discharge confirmation long-time detection flag and shifts to the next processing (processing of step 2520). Even if No in step 2504 or step 2510, the process moves to the next process (process in step 2520).

Next, in step 2520, the CPUMC of the main control board M determines whether or not the input from the total ejection confirmation sensor C90s is ON for the fraud detection time or longer. If Yes in step 2520, in step 2522, the CPUMC of the main control board M turns on the discharge confirmation long-time detection flag, and proceeds to the next process (process of step 2600). On the other hand, if No in step 2520, the process proceeds to the next process (process in step 2600).

Next, FIG. 21 is a flowchart of the out-port entrance detecting process according to the subroutine of step 2600 in FIG. First, in step 2602, the CPUMC of the main control board M determines whether or not the out-port detection continuation flag is off. If Yes in step 2602, in step 2604, the CPUMC of the main control board M detects that the input from the out-mouth entrance detection device D36s is the entrance detection time (the above-mentioned time or more, the out-mouth entrance detection device D36s detects the input). Then, it is determined whether or not it is ON for a time equal to or longer than the time when it is considered that there is a ball in the outlet D36 or the upper outlet D36-2. If Yes in step 2604, in step 2606, the CPUMC of the main control board M turns on the outlet detection continuation flag, in step 2608, adds 1 to the incoming ball number counter value, and proceeds to step 2620. ..

On the other hand, in the case of No in step 2602, in step 2610, the CPUMC of the main control board M detects the end time of the input from the out-outlet entrance detecting device D36s (the above-mentioned time or more, the out-entrance entering detecting device D36s inputs the input). If not detected, it is determined whether or not the game ball is OFF for more than the time it is considered that the game ball has passed through the out-mouth entrance ball detection device D36s). If Yes in step 2610, in step 2612, the CPU MC of the main control board M turns off the outlet detection continuation flag. Next, in step 2615, the CPUMC of the main control board M turns off the outlet long time detection flag, and proceeds to step 2620. On the other hand, if No in step 2604 or step 2610, the process moves to step 2620.

Next, in step 2620, the CPUMC of the main control board M determines that the input from the out-door entrance detecting device D36s is a false detection time (when the out-mouth entering-ball detecting device D36s has detected the input for the incorrect detection time or more). , It is determined whether or not it is ON for more than a period of time when it is considered that an illegal ball has been entered into the outlet D36 or the upper outlet D36-2. If Yes in step 2620, in step 2622, the CPUMC of the main control board M turns on the out-port long-time detection flag, and proceeds to the next process (the process of step 2700). On the other hand, if No in step 2620, the process proceeds to the next process (process in step 2700).

Next, FIG. 22 is a flowchart of the prize ball number determination processing according to the subroutine of step 2700 in FIG. First, in step 2702, the CPUMC of the main control board M determines whether or not the player has entered the first main game starting opening (A10). If Yes in step 2702, in step 2704, the CPU MC of the main control board M adds the prize ball payout amount (3 in this example) related to the first main game starting opening A10 to the counter value of the prize ball number counter. To do. Next, in step 2708, the CPUMC of the main control board M temporarily stores information (for example, information relating to the number of prize balls paid out) indicating that prize balls related to the first main game starting opening A10 are to be paid out, and step 2709. Move to -1. On the other hand, if No in step 2702, the process moves to step 2709-1.

Next, in step 2709-1, the CPUMC of the main control board M determines whether or not the player has entered the first main game starting opening (A10-2). If Yes in step 2709-1, in step 2709-2, the CPUMC of the main control board M sets the counter value of the prize ball number counter to the prize ball payout amount related to the first main game starting opening A10-2 (this example). Then, 1) is added. Next, in step 2709-3, the CPUMC of the main control board M temporarily stores information (for example, information regarding the number of prize balls paid out) indicating that prize balls related to the first main game starting opening A10-2 are paid out. Then, the process proceeds to step 2712. On the other hand, if No in step 2709-1, the process moves to step 2712.

Next, in step 2712, the CPUMC of the main control board M determines whether or not the second main game start flag is on. If Yes in step 2712, in step 2714, the CPUMC of the main control board M adds the prize ball payout number (1 in this example) for the second main game starting opening B10 to the counter value of the prize ball number counter. To do. Next, in step 2718, the CPUMC of the main control board M temporarily stores information (for example, information regarding the number of prize balls paid out) indicating that prize balls related to the second main game starting opening B10 are to be paid out, and step 2720. Move to. On the other hand, if No in step 2712, the process moves to step 2720.

Next, in step 2720-1, the CPUMC of the main control board M determines whether or not the player has entered the auxiliary game electric accessory E10 (the distribution entrance C20). If Yes in step 2720-1, in step 2720-2, the CPUMC of the main control board M adds the prize ball payout number (1 in this example) related to the electric accessory to the counter value of the prize ball number counter. To do. Next, in step 2720-3, the CPUMC of the main control board M temporarily stores information (for example, information regarding the number of prize balls paid out) that pays out prize balls related to the electric accessory, and proceeds to step 2722. To do. On the other hand, if No in step 2720-1, the process moves to step 2722.

Next, in step 2722, the CPUMC of the main control board M determines whether or not the first (second) special winning opening entry flag is on. If Yes in step 2722, in step 2723, the CPUMC of the main control board M turns off the first (second) special winning opening ball flag. Next, in step 2724, the CPUMC of the main control board M sets the counter value of the prize ball number counter to the prize ball payout number (15 in this example) associated with the first prize hole C10 or the second prize hole C20. The number of prize balls paid out (5 in this example) is added. Next, in step 2728, the CPUMC of the main control board M informs that the prize balls related to the first special winning opening C10 (the second special winning opening C20) are to be paid out (for example, information related to the number of prize balls paid out). Is temporarily stored, and the process proceeds to step 2732. On the other hand, if No in step 2722, the process moves to step 2732.

Next, in step 2732, the CPUMC of the main control board M determines whether or not the general winning opening entry flag is on. If Yes in step 2732, in step 2733, the CPU MC of the main control board M turns off the general winning opening entry flag. Next, in step 2734, the CPUMC of the main control board M adds the prize-ball payout amount (10 in this example) related to the general winning opening to the counter value of the prize-ball number counter. Next, in step 2738, the CPUMC of the main control board M temporarily stores information (for example, information regarding the number of prize balls paid out) indicating that prize balls related to the general winning opening are to be paid out, and the next process (step 1100). Process). On the other hand, if No in step 2732, the process moves to the next process (process in step 1100).

Next, FIG. 23 is a flowchart of the auxiliary game content determination random number acquisition process according to the subroutine of step 1100 in FIG. First, in step 1102, the CPUMC of the main control board M determines whether or not a game ball has entered (inflowed or passed in the case of a gate) in the auxiliary game starting opening H10. In the case of Yes in step 1102, in step 1103, the CPUMC of the main control board M transmits an auxiliary game start opening ball entry command, which is a command related to the fact that the auxiliary game starting opening H10 is entered, to the sub-main control section SM. Is set in the command transmission buffer (transmitted to the sub-main control unit SM side by the control command transmission process of step 1999), and the process proceeds to step 1110. Next, in step 1110, the CPUMC of the main control board M determines whether or not the number of reserved balls is the upper limit (for example, four). If Yes in step 1110, in step 1112, the CPU MC of the main control board M acquires an auxiliary game content determination random number (for example, an auxiliary game symbol winning random number). Next, in step 1114, the CPU MC of the main control board M adds 1 to the holding sphere in the form of setting it in the RAM area of the main control board M together with the information on the number of holdings, and the next process The process proceeds to step 1200). Even if No in Steps 1104 and 1110, the process proceeds to the next process (process in Step 1200). Here, in the present embodiment, since the auxiliary game starting port H10 has the shape of a gate, the game ball entering the auxiliary game starting port H10 (passing through the auxiliary game starting port H10) continues on the game board surface. While it will flow down, it can enter the ball entrance (big prize hole, etc.) downstream of the auxiliary game starting hole H10, while the game ball that entered the big prize hole flows down into the back of the game board surface. After that, it is configured so as not to enter the other entrances. Even if a game ball enters the auxiliary game starting port H10 (a game ball passes through the auxiliary game starting port H10), prize balls are not paid out.

Next, FIG. 24 is a flowchart of the electric accessory driving determination processing according to the subroutine of step 1200 in FIG. First, in step 1202, the CPU MC of the main control board M determines whether or not the electric accessory opening flag is off. In the case of Yes in step 1202, in step 1204, the CPU MC of the main control board M determines whether or not the auxiliary game symbol changing flag is off. In the case of Yes in step 1204, in step 1206, the CPU MC of the main control board M determines whether or not there is a reserve ball related to the auxiliary game symbol. If Yes in step 1206, in step 1216, the CPUMC of the main control board M acquires the game state of the auxiliary game side (the flag state of the auxiliary game short-time flag), and also refers to the auxiliary game symbol determination lottery table, A stop symbol is determined based on the obtained game state of the auxiliary game side and the auxiliary game symbol winning random number based on the holding ball (for example, when the auxiliary game time saving flag is on, it is higher than when it is off). The winning symbol is selected with a probability) and is temporarily stored in the RAM area of the CPUMC of the main control board M.

Here, the right side of the figure is an example of the auxiliary game stop symbol determination lottery table. As shown in the table, in this example, the stop symbol has "D0, D1", and the stop symbol which is the hit symbol is "D1", and the hit symbol is released due to the stop. The opening mode of the electric accessory that will be different is, in the non-time shortening game, when the stopped symbol is "D1", the opening mode is (1.6 seconds open→0.2 seconds closed→0.2 seconds Open → closed). Further, at the time shortening game, when the stopped symbol is "D1", the opening mode is (0.2 seconds open→1.6 seconds closed→5.8 seconds open→closed). Although the probability is almost the same, the stop symbol is likely to be a lost symbol "D0" during the non-time shortening game, and the stop symbol is likely to be a hit symbol "D1" during the time shortening game.

Next, in step 1218, the CPUMC of the main control board M, based on the game state of the auxiliary game side (the flag state of the auxiliary game short time flag), the auxiliary game symbol variation management timer determines the variation time of the auxiliary game symbol. Time (for example, 1 second when the auxiliary game time saving flag is on, 1.1 seconds when the auxiliary game time saving flag is off) is set. Then, in step 1220, the CPU MC of the main control board M turns on the auxiliary game symbol changing flag. Next, in step 1222, the CPUMC of the main control board M updates the holding information recorded in the RAM area of the CPUMC of the main control board M after subtracting 1 from the holding ball related to the auxiliary game symbol, and the auxiliary. After starting the timer for game symbol fluctuation management, the variable display of the auxiliary game symbol is started on the auxiliary game symbol display portion H21g.

Next, in step 1224, the CPU MC of the main control board M refers to the auxiliary game symbol variation management timer and determines whether or not a predetermined time period related to the variation time of the auxiliary game symbol has been reached. If Yes in step 1224, in step 1226, the CPUMC of the main control board M acquires the stop symbol of the auxiliary game symbol, and confirms the stop symbol of the acquired auxiliary game symbol on the auxiliary game symbol display unit H21g. To do. Then, in step 1228, the CPU MC of the main control board M turns off the auxiliary game symbol changing flag. Next, in step 1230, the CPU MC of the main control board M determines whether or not the stop symbol of the auxiliary game symbol is “win” (D1 in this example). If Yes in step 1230, in step 1232, the CPUMC of the main control board M determines the opening mode based on the gaming state and the winning symbol on the auxiliary game side, and the electric auditors opening time of the electric auditors opening timer ( Set a predetermined time for opening and closing time). Next, in step 1234, the CPUMC of the main control board M turns on the electric accessory opening flag. Then, in step 1236, the CPU MC of the main control board M releases the auxiliary game electric accessory E10, and proceeds to step 1242. Even if No in step 1202, the process proceeds to step 1242.

Next, in step 1242, the CPUMC of the main control board M refers to the electric accessory opening timer to determine whether or not a predetermined time related to the opening time of the electric accessory has been reached. If Yes in step 1242, in step 1244 and step 1246, the CPU MC of the main control board M closes the auxiliary game electric accessory E10 and turns off the electric accessory opening flag, and performs the next process (step 1300). Process).

If No in step 1204, the process moves to step 1224, and if No in steps 1206, 1224, 1230 and 1242, the process moves to the next process (process of step 1250).

Further, in this flowchart, for convenience, immediately after the stop symbol is displayed in step 1226, the process proceeds to the next step, but the present invention is not limited to this. In that case, it may be configured to move to the next process after a stop display fixed time of about 500 ms (for example, this process is performed by performing a branch process using a stop display fixed flag and a timer). Achievable). In addition, there may be a plurality of auxiliary game content determination random numbers, auxiliary game symbol winning random number for determining the success or failure of the auxiliary game, auxiliary game symbol stop symbol random number for determining the stop symbol of the auxiliary game symbol, auxiliary game symbol It may be provided with an auxiliary game symbol variation mode random number or the like for determining the variation time of.

Although not shown, in a single opening operation of the auxiliary game electric accessory E10 (opening operation based on the stop of the symbol per auxiliary game), a predetermined number of game balls in the auxiliary game electric accessory E10 ( For example, 10 balls) is entered, the opening operation of the auxiliary game electric auditors product E10 is configured to end, that is, the opening time of the auxiliary gaming electric auditors product E10 ends, or the auxiliary game electric auditor When the predetermined number (for example, 10 balls) of game balls enter the auxiliary game electric role object E10 during the opening period of the object E10, whichever comes first, the auxiliary game electric role object E10 is released (open). Is configured to end. In addition, the total time that the ordinary electric auditors object is opened in the non-time shortened gaming state (auxiliary gaming time shortened flag ON) is 1.8 seconds, and the time when the ordinary electric auditors object is opened in the time shortened gaming state is The total is 6.0 seconds, and in any game state, it is configured not to exceed 6 seconds throughout the maximum opening time, and the maximum number of winning prizes during operation does not exceed 10 in general. Thus, it is predetermined for each game state (whether it is a time-reduced game state or a non-time-reduced game state).

In addition, in this example, when the normal symbol (auxiliary gaming symbol) that has been the trigger for the operation of the normal electric auditors object (auxiliary gaming electric auditors item E10) is confirmed and displayed in a hit mode, immediately (eg, It is configured to operate within 500 ms, which is shorter than the symbol fluctuation time, and it is possible to clearly associate with which trigger the normal electric accessory is operating. Incidentally, in order to prevent a large number of game balls from winning during the closing operation of the ordinary electric accessory (auxiliary game electric accessory E10) (during the operation of opening → closing), the ordinary electric accessory (auxiliary game) The drive source (solenoid) is selected so that the electric accessory E10) will return to the inactive state in a short time, so that the game balls won more than necessary and there is no big difference from the payout design. It has become.

Next, FIG. 25 is a diagram showing the internal structure of the auxiliary game electric accessory E10 (sorting entrance C20). Inside the auxiliary game electric accessory E10, the first non-electric accessory HD-1 is opened by the entry of the game ball. The first opening entrance N1 (first opening entrance entrance ball). Detection device N1s), and the second non-electric accessory HD-2 is opened by the game ball entering, the second opening entrance N2 (second opening entrance entrance detection device N2s) , Has a distribution member FB that distributes the game balls that have entered the auxiliary game electric accessory E10 to the first opening entrance N1 and the second opening entrance N2.

First, when the operation of the upper part of the figure is described in detail, when the distribution member FB is in the first mode, it is in a state of being swung to the right so as to block the flow path to the first opening entrance N1. The game ball that has entered the auxiliary game electric accessory E10 is configured to easily enter the second opening entrance N2 and difficult to enter the first opening entrance N1. Next, the operation of the lower part of the figure will be described in detail. When the distribution member FB is in the second mode, it is in a state of being swung to the left side so as to block the flow path to the second opening entrance N2. The game ball that has entered the auxiliary game electric accessory E10 is difficult to enter the second opening entrance N2, and is configured to easily enter the first opening entrance N1. Further, as will be described later, the distribution member FB is configured to start driving from the first opening timing when the auxiliary game electric accessory E10 is opened, and to be driven as in “first aspect→second aspect”. ing.

Next, FIG. 26 is a flowchart of the distribution member drive control process according to the subroutine of step 1250 in FIG. First, in step 1250-1, is the CPU MC of the main control board M turning off the distribution member driving flag (a flag that is turned on while the distribution member is driven based on the opening of the electric accessory). Determine whether or not. In the case of Yes in step 1250-1, in step 1250-2, the CPUMC of the main control board M has reached the first opening timing of the electric accessory (from the timing when the electric accessory first opens, the distributing member). Drive is started) is determined. If Yes in step 1250-2, in step 1250-3, the CPU MC of the main control board M sets an initial value (7.6 in this example) to the distribution member drive timer (decrement timer) and starts. Next, in step 1250-4, the CPUMC of the main control board M turns on the sorting member driving flag, and proceeds to step 1250-5. Even if No in step 1250-1, the process proceeds to step 1250-5. Next, in step 1250-5, the CPUMC of the main control board M has the distribution member drive timer value reaching the drive switching timing (timer value=5.8) (the distribution member drive timer is a decrement timer). Therefore, the distribution member driving timer value at the timing of 1.8 seconds from the start of driving the distribution member is 5.8). If Yes in step 1250-5, in step 1250-6, the CPU MC of the main control board M drives the distribution member from the first mode to the second mode (the initial position is the first mode), Move to the next process. If No in step 1250-5, in step 1250-7, the CPU MC of the main control board M determines whether or not the distribution member drive timer value is 0. If Yes in step 1250-7, in step 1250-8, the CPUMC of the main control board M drives the distribution member from the second mode to the first mode. Next, in step 1250-9, the CPUMC of the main control board M turns off the sorting member driving flag and shifts to the next processing. Even if No in step 1250-2 or 1250-7, the process proceeds to the next process.

Next, the middle part of FIG. 26 is an operation diagram of the electric accessory and the distribution member. First, the distribution member FB is driven from the first mode (initial position) to the second mode at a predetermined timing (1.8 seconds from the start of driving). Here, in the non-time reduction game state, the electric member is opened long during the period in which the distribution member is the first mode (1.6 seconds, which is the first half of the opening period of the electric member described above). Open), it becomes easy to enter the game ball. On the other hand, in the time shortening game state, the electric accessory is opened long during the period in which the distribution member is in the second mode (release of 5.8 seconds, which is the latter half of the above-mentioned electric accessory open period). ), and is configured to facilitate the entry of game balls. In addition, the lower part of FIG. 26 is a table showing an opening mode of the electric accessory and a displacement mode of the distribution member. As described above, in the opening pattern of the electric accessory, when the auxiliary game short time flag is on, the total opening time or the maximum opening time (in the case of opening a plurality of electric electric goods) is longer than when the auxiliary game short time flag is off. It becomes longer, and when the auxiliary game short time flag is on, it is easier to enter the game ball into the distribution ball entrance (auxiliary game electric auditor E10) than when the auxiliary game short time flag is off. Is becoming As described above, the distribution member guides the game ball to enter the second opening entrance N2 in the case of the first mode, and the first opening case in the case of the second mode. The game ball is guided so as to enter the ball opening N1. Although not shown, in the non-time reduction game state, the state in which the sorting member is driven in the second mode (the state in which the timer value of the sorting member driving timer is between 5.8 and 0) ), the opening start timing of the electric auditors may be newly reached. Therefore, at the same time as turning off the electric auditors opening flag of step 1246 in the electric auditors driving determination process shown in step 1200, the sorting member is set to the first mode. Alternatively, the timer value of the sorting member driving timer may be initialized.

Next, FIG. 27 is a flowchart of the first non-electric auditors product drive control process according to the subroutine of step 1280 of FIG. First, in step 1280-1, the CPUMC of the main control board M causes the first non-electric auditors product open flag (first non-electric auditors product opening/closing detection attached to the opening/closing part of the first non-electric auditors product HD-1). When the sensor is in the non-detection state (OFF), it is determined whether the first non-electric accessory HD-1 is determined to be open and is turned on). If Yes in step 1280-1, CPUMC of the main control board M determines in step 1280-2 whether or not a game ball has entered the first opening entrance N1. If Yes in step 1280-2, in step 1280-3, the CPUMC of the main control board M turns on the first non-electric auditors accessory opening flag. If No in step 1280-1, in step 1280-5, the CPU MC of the main control board M, when the first non-electric accessory opening/closing detection sensor is turned on, turns off the first main game starting opening. Whether or not a predetermined number (the number of balls that the first non-electric accessory HD-1 physically closes due to the weight of the game ball, two in this example) has entered (A10-2) Determine whether. If Yes in step 1280-5, in step 1280-6, the CPUMC of the main control board M does not satisfy the error occurrence condition (in this example, when the first non-electric accessory is closed (first non-electric accessory). When the electric accessory opening/closing detection sensor is changed from off to on), only one ball has entered the first main game starting opening (A10-2), or four balls have entered It is determined whether or not a winning action or an event determined to have been opened/closed is observed multiple times). If Yes in step 1280-6, in step 1280-8, the CPU MC of the main control board M turns off the first non-electric auditors accessory opening flag, and proceeds to the next process. In addition, also in the case of No in step 1280-5 or step 1280-2, the process proceeds to the next process. In addition, in the case of No in step 1280-6, in step 1280-9, it is notified that there is an error and error processing is executed (error recovery conditions include, for example, passage of an abnormality notification period of a predetermined time, power supply It may be turned off→turned on, RAM clear may be executed, etc.), and the process proceeds to step 1280-8.

Next, FIG. 28 is a flowchart of the second non-electric auditors product drive control process according to the subroutine of step 1290 of FIG. First, in step 1290-1, the CPUMC of the main control board M causes the second non-electric auditor accessory open flag (second non-electric auditor accessory open/close detection attached to the opening/closing part of the second non-electric auditor accessory HD-2). When the sensor is in the non-detection state (OFF), it is determined whether or not the flag that turns on by determining that the second non-electric accessory HD-2 is open) is off. If Yes in step 1290-1, in step 1290-2, the CPUMC of the main control board M determines whether or not the player has entered the second opening entrance N2. If Yes in step 1290-2, in step 1290-3, the CPU MC of the main control board M turns on the second non-electric auditors open flag. In addition, in the case of No in step 1290-1, in step 1290-5, the CPUMC of the main control board M, when the second non-electric accessory opening/closing detection sensor is turned on from the second main game starting opening It is determined whether or not a predetermined number (the second non-electric accessory HD-2 is the number of balls to be physically closed due to the weight of the game ball, which is two in this example) has entered B10. .. If Yes in step 1290-5, in step 1290-6, the CPUMC of the main control board M does not satisfy the error occurrence condition (in the present example, when the second non-electric accessory is closed (the second non-electric accessory). When the electric accessory opening/closing detection sensor is changed from OFF to ON), the second main game starting opening B10 has only one ball entered, or four balls entered, such as an irregular winning operation, It is determined whether or not the event that was determined to have been opened and closed was observed multiple times). If Yes in step 1290-6, in step 1290-8, the CPU MC of the main control board M turns off the second non-electric auditors accessory opening flag, and proceeds to the next process. Even if No in step 1290-5 or step 1290-2, the process proceeds to the next process. Further, in the case of No in step 1290-6, in step 1290-9, the fact that there is an error is notified and error processing is executed (error recovery conditions include, for example, the passage of an abnormality notification period of a predetermined time, power supply It may be turned off→on, RAM clear may be executed, etc.), and the process proceeds to step 1290-8.

Next, FIG. 29 is a flowchart of the main game content determination random number acquisition process according to the subroutine of step 1300 in FIG. First, in step 1302, the CPUMC of the main control board M determines the first main game starting mouth entrance information from the first main game starting entrance detecting device A11s (first main game starting entrance detecting device A11s-2). Is received. In the case of Yes in step 1302, in step 1304, the CPU MC of the main control board M determines whether or not there are upper limit (for example, four) reserved balls related to the main game (especially, the first main game side). If Yes in step 1304, in step 1306, the CPU MC of the main control board M acquires a first main game content determination random number. In the present embodiment, as the first main game content determination random number, the winning/non-winning lottery random number for determining the win/fail, the symbol lottery random number for determining the winning symbol, and the variation pattern (variation time) of the special symbol are determined. The three random numbers of the variation mode lottery random number for performing are acquired. By the way, these three random numbers are generated by random number generation means having different update cycles and random number ranges, and are sequentially acquired at this timing. Next, in step 1308, the CPU MC of the main control board M temporarily stores (holds) the acquired first main game content determination random number. Next, in step 1310, the CPU MC of the main control board M determines whether or not the special game execution flag is off. In the case of Yes in step 1310, in step 1314, the CPUMC of the main control board M pre-determines the hit/non-win result and the stop symbol relating to the stored hold, based on the hold information (win/win lottery random number and symbol determination random number). Next, in step 1316, the CPUMC of the main control board M sets a command related to the new hold success/failure result and the preliminary determination result of the stop symbol information in the command transmission buffer for transmitting to the sub-main control unit SM. (It is transmitted to the sub-main control section SM side by the control command transmission process of step 1999), and the routine proceeds to step 1318.

Next, in step 1318, the CPUMC of the main control board M pre-determines the stored variation mode group related to suspension based on the suspension information (random number for variation mode determination) (for the variation mode group, the main game table). 3), and proceeds to step 1320. In this embodiment, one variation mode group is configured to include a plurality of types of variation modes (variation time). Even if No in Step 1310 or Step 1312, the process proceeds to Step 1320. Next, in step 1320, the CPUMC of the main control board M issues a command relating to the generation of a new suspension (a suspension generation command of the first main game content determination random number, a command relating to the variation mode group command, etc.). It is set in the command transmission buffer for transmission to the SM (transmitted to the sub-main control unit SM side by the control command transmission process of step 1999), and the process proceeds to step 1322. When the symbol information is configured to be transmitted to the sub-control board S side as in the present embodiment, an effect suggesting a big hit may be executed as an effect to be executed on the sub-control board S side. In such a case, it is desirable that the player can be notified of the stop symbol of the main game symbol that is the big hit (the stop symbol is informed only when the stop symbol of the main game symbol is the big hit). Also, in the case of No in step 1302 or step 1304, the process proceeds to step 1322. Although the first main game content determination random number is temporarily stored in step 1308, the processing relating to the first main game content determination random number will be described in detail. (1) First main game starting opening A10 (A10-2) The first main game content determination random number is acquired when the player enters the ball and is stored in the register. (2) The first main game content determination random number stored in the register is stored in the RAM of the main control board M, and based on the first main game content determination random number stored in the register, the variation start of the main game symbol is started. Execute pre-reading lottery in front. (3) The first main game content determination random number stored in the RAM of the main control board M is stored in the register at the start of fluctuation of the main game symbol, and based on the first main game content determination random number stored in the register. To determine whether or not to win or not (may be performed based on the first main game content determination random number stored in the RAM of the main control board M). Incidentally, when the prefetch lottery can be executed on the second main game side, the same process may be executed for the second main game content determination random number.

As described above, in the present embodiment, the variation mode group is determined when the main game content determination random number (the first main game content determination random number or the second main game content determination random number) is acquired (or when the hold occurs). ing.

Incidentally, the main game content determination random number information and the variation mode group information may be transmitted to the sub-control board S side at the timing when the hold occurs, but further, the information to be transmitted to the sub-control board S side is Without being limited to this, information related to the stop pattern of the main game symbol, information related to the profit mode of the main game symbol that is a big hit (the number of rounds of special games related to the main game symbol scheduled to be stopped, etc.) Information regarding the number of holdings (only the number of holdings on the winning side of the first main game side or the second main game side, or the number of holdings on both the first main game side and the second main game side), etc. May be configured to be transmitted.

Next, in step 1322, the CPU MC of the main control board M determines whether or not the second main game starting mouth entrance information is received from the second main game starting entrance detecting device B11s. In the case of Yes in step 1322, in step 1324, the CPUMC of the main control board M determines whether or not the number of reserved balls regarding the main game (especially the second main game side) is not the upper limit (for example, four). If Yes in step 1324, in step 1326, the CPUMC of the main control board M acquires the second main game content determination random number. In addition, in the present embodiment, as the second main game content determination random number, three random numbers, that is, the win/fail lottery random number, the symbol lottery random number, and the variation mode lottery random number are acquired, as in the first main game symbol determination means. By the way, an acquisition range of each random number of the first main game content determination random number and an acquisition range of each random number of the second main game content determination random number (for example, a win/loss lot number for the first main game and a win/loss lot number for the second main game) The acquisition range) is set to the same. Next, in step 1328, the CPUMC of the main control board M temporarily stores (holds) the acquired second main game content determination random number. Next, in step 1330, the CPU MC of the main control board M determines whether or not the special game execution flag is off. In the case of Yes in step 1330, in step 1334, the CPUMC of the main control board M preliminarily determines the hit/non-win result and the stop symbol relating to the stored hold, based on the hold information (win/win lottery random number and symbol determination random number). Next, in step 1336, the CPU MC of the main control board M sets a command related to the new hold success/failure result and the preliminary determination result of the stop symbol information in the command transmission buffer for transmitting to the sub-main control unit SM. (Transmitted to the sub-main control unit SM side by the control command transmission process of step 1999), and then proceeds to step 1338.

When the result in step 1330 is No, the process proceeds to step 1340.

Next, in step 1338, the CPUMC of the main control board M pre-determines the stored variation mode group according to the stored information (random number for variation mode determination) (for the variation mode group, the main game table). 3), and the process proceeds to step 1340. Next, in step 1340, the CPUMC of the main control board M issues a command related to a new hold occurrence (a hold occurrence command of the second main game content determination random number, a command related to the variation mode group command, etc.). It is set in the command transmission buffer for transmission to the SM (transmitted to the sub-main control unit SM side by the control command transmission process of step 1999), and the process proceeds to the next process (process of step 1400). Also, in the case of No at step 1322 or step 1324, the process moves to the next process (process of step 1400).

In the present embodiment, as a result of the preliminary determination, the second main game side is configured to transmit the command related to the variation mode group, but the second main game side transmits the command related to the variation mode group. It may be configured not to transmit. That is, as a result of the preliminary determination, only the command relating to the result of winning and the preliminary determination result of the stop symbol information may be transmitted.

Although the storage of the first main game content determination random number and the storage of the second main game content determination random number are executed in steps 1308 and 1328, the main game content determination random number is stored in the storage area of the RAM of the main control board. In the case of storing, a dedicated storage area is secured, and only the information related to the "main game content determination random number" is stored in the byte that stores the information related to the main game content determination random number (various timers). It is preferable to configure so as not to store other information such as a value (when operating other data stored in the same 1 byte, information relating to the main game content determination random number is rewritten due to noise or the like. To prevent it from getting lost). Further, for the win/loss lottery random number, a change in the game state (from the already-recorded pending game state of the hold state) after the win/win lottery random number is acquired until the win/loss lottery related to the win/loss lottery random number is executed. Not only the change but also the change in the game state may occur due to the newly generated hold, so the game state at the time of executing the win/win lottery associated with the lottery random number may be unpredictable), so the win/win lottery The lottery random number is stored until the process is executed. In the present embodiment, the command to the sub-main control unit SM relating to the hold information is the hold related to the first main game or the hold related to the second main game in any game state. Regardless of whether it is configured to be able to send the command, the command to the sub-main control unit SM related to the information on hold is sent only when the hold related to the first main game occurs in the non-time reduction game state. On the other hand, even in the time shortening game state, as shown in the game state transition diagram to be described later, since the holding digestion related to the first main game is the main constituent, it is configured to be transmitted only when the hold related to the first main game occurs. Good. In addition, in the present embodiment, when the first main game content determination random number is stored, the special game is not being executed, and it is in the non-time shortening game state, and further the fluctuation of the symbol relating to the second main game. As the display, the variable display that is a big hit is not executed, and in this case, it is configured to transmit to the sub control board S side the information regarding the hit result, the stop symbol, and the variation mode group related to the new hold.

Next, FIG. 30 is a flowchart of the first main game symbol display process (second main game symbol display process), which is related to the subroutine of the main game symbol display process in FIG. This figure is configured to be able to execute a so-called parallel lottery, in which the main game symbols of both the first main game symbol and the second main game symbol are simultaneously drawn in parallel. Since this process is substantially the same as the first main game symbol side and the second main game symbol side, the first main game symbol side will be mainly described and the second main game symbol side will be described. Write in parentheses. First, in step 1403, the CPUMC of the main control board M determines whether or not the fluctuation start condition is satisfied. Here, the fluctuation start condition is not during the special game (or the condition device is operating), and the main game symbol that is the control target is not changing the main game symbol, and of the main game symbol that is the control target. The condition is that there is a hold. Although not shown in this example, if a fixed fixed time (after the fixed display of the main game symbol is displayed, the fixed display symbol is stopped and displayed) is provided, during the fixed fixed time, the variable start condition of the next variation May not be satisfied.

If Yes in step 1403, in step 1405 and step 1406, the CPU MC of the main control board M temporarily stores the first main game content determination random number (second main game content determination random number) relating to the present symbol variation. Is read out, deleted from the holding information, and the remaining information temporarily stored is shifted (holding digest processing). Next, in step 1410-1, the CPUMC of the main control board M refers to the first main game win/loss lottery table (second main game win/loss lottery table) corresponding to each gaming state, and the first main game content Based on the determined random number (second main game content determination random number) (particularly, the winning lottery random number), the main game symbol win/win lottery is executed.

Here, FIG. 31 (main game table 1) is an example of a first main game win/loss lottery table (second main game win/loss lottery table). As shown in this example, in the present embodiment, the jackpot winning probability in the probability varying game state is configured to have a higher probability (=probability change) than the jackpot winning probability in the non-probability varying game state. .. The winning probability is merely an example, and the present invention is not limited to this.

Next, in step 1410-2, the CPUMC of the main control board M refers to the first main game symbol determination lottery table (second main game symbol determination lottery table), and the main game symbol win/loss result and the first A stop symbol relating to the main game symbol is determined based on the main game content determination random number (second main game content determination random number) (particularly, the symbol lottery random number), and these are temporarily stored.

Here, FIG. 32 (main game table 2) is an example of a first main game symbol determination lottery table (second main game symbol determination lottery table). As shown in this example, in the present embodiment, when a big hit is won, from among a plurality of main game symbol candidates (in this example, "α1, α2, α3" and "β1, β2, β3") One main game symbol is configured to be determined as a jackpot symbol. In addition, the number of rounds of the special game determined with reference to the main game symbol is all 10R. It should be noted that the random number value and the type of the stop symbol are also merely examples, and the present invention is not limited to this. You may}

Next, in step 1410-4, the CPUMC of the main control board M refers to the first main game variation mode determination lottery table (second main game variation mode determination lottery table) corresponding to each game state, The variation mode of the main game symbol is determined based on the game symbol win/loss result and the first main game content determination random number (second main game content determination random number) (particularly, variation mode random number), and these are determined on the main control board M. It is temporarily stored in the RAM area.

Here, the main game table 3 shown in FIGS. 33 to 35 is an example of a first main game variation mode determination lottery table (second main game variation mode determination lottery table). As shown in this figure, in the present embodiment, based on the winning/winning lottery result of the main game symbol, the main game time saving flag state, the variation mode (variation time) of the main game symbol for a certain random number value can be determined Has been done. For example, for a random number value, if the winning/winning lottery result of the main game symbol is a hit, it is easy to determine a variation mode in which the variation time is relatively long, and the main game time saving flag is on (time saving game The state) is configured so that the variation mode in which the variation time is relatively short can be easily determined. Note that this example is merely an example, and there is no limitation on the type of variation mode (variation time), the selection rate, or the like. 33 to 35, the variation mode group is provided even in a situation (gaming state or the like) in which information related to the variation mode group is not transmitted to the sub-control board S, but the invention is not limited to this. The variation mode group may be provided only in the situation of transmitting to the control board S side. Regarding the main game time saving flag, which of the main game probability change flag (the flag that operates during the high probability state) and the auxiliary game time shortening flag (the flag that operates during the advantageous game state on the auxiliary game side) operates at the same time? Accordingly, it may be configured to change the type of main game for reducing the variation time or selectively operate any of the plurality of main game time saving flags. For example, when the auxiliary game time saving flag is activated, the first main game variation mode determination lottery table is set to facilitate the determination of the variation mode for a short time for the time saving game, and the main game probability variation flag is turned on ( When a high probability game is being played) and the auxiliary game time saving flag is off, the second main game fluctuation mode determining lottery table may be set so that the fluctuation mode for a short time for the time saving game is easily determined.

Next, in step 1412, the CPUMC of the main control board M, the command relating to the temporarily stored main game symbol (stop symbol information, attribute information of the stop symbol, variation mode information, etc.) and the command relating to the current game state ( The pattern variation display start instruction command) is set in the command transmission buffer for transmission to the sub-main control unit SM side (transmitted to the sub-main control unit SM side by the control command transmission process in step 1999). Next, in step 1414, the CPUMC of the main control board M sets a predetermined time relating to the variation time of the main game symbol in the first and second main game symbol variation management timers. Next, in step 1416, the CPUMC of the main control board M, the first main game symbol display portion A21g (second main game symbol display portion) of the first main game symbol display device A20 (second main game symbol display device B20). On B21g), according to the temporarily stored variation mode, the variation display of the main game symbol is started. Next, in step 1418, the CPUMC of the main control board M turns on the changing flag, and proceeds to step 1419-1.

Next, in step 1419-1, the CPUMC of the main control board M determines whether or not the auxiliary game short time flag is ON (=high base).

If Yes in step 1419-1, in step 1419-2, the CPUMC of the main control board M is a variation in which the variation this time is a big hit in the first main game symbol (a variation in which the second main game symbol is a big hit). ) Is determined.

If Yes in step 1419-2, in step 1419-3, the CPU MC of the main control board M turns off the auxiliary game shortened flag (that is, low base), and proceeds to the process of step 1422.

On the other hand, if No in steps 1419-1 and 1419-2, the process proceeds to step 1422.

On the other hand, in the case of No in step 1403, in step 1420, the CPUMC of the main control board M determines whether or not the changing flag is on. If Yes in step 1420, the process moves to step 1422, and if No in step 1420, the process moves to the next process.

Next, in step 1422, the CPUMC of the main control board M determines whether or not a predetermined time relating to the variation time of the main game symbol has been reached. If Yes in step 1422, in step 1422, the CPU MC of the main control board M sends information (symbol finalization display instruction command) indicating that the variation of the symbol is finished to the command transmission for transmitting to the sub-main controller SM side. It is set in the buffer (transmitted to the sub-main control unit SM side by the control command transmission process of step 1999). Next, in step 1424, the CPUMC of the main control board M, the first main game symbol display portion A21g (second main game symbol display portion) of the first main game symbol display device A20 (second main game symbol display device B20). B21g) stop the variable display of the main game symbol on the display control the stop symbol that is temporarily stored as a fixed stop symbol. Next, in step 1426, a command (command for transmitting to the sub side) related to information indicating that the symbol is stopped and displayed is set. Next, in step 1428, the CPUMC of the main control board M turns off the changing flag.

Next, in step 1430, the CPU MC of the main control board M determines whether or not the stop symbol of the main game symbol is a jackpot symbol. If Yes in step 1430, in step 1432, the CPU MC of the main control board M turns on the condition device operation flag, and proceeds to step 3350.

On the other hand, in the case of No in step 1430, in step 1434, the CPUMC of the main control board M determines whether or not the stop symbol is the small hit symbol. If Yes in step 1434, in step 1436, the CPU MC of the main control board M turns on the small hit flag, and proceeds to step 1500. If No in step 1434, the process moves to step 3350.

Next, in step 3350, the CPUMC of the main control board M executes the other main game variation control process described later.

Next, in step 1500, the CPUMC of the main control board M executes a specific game end determination process described later, and shifts to the next process. Even if No in step 1420, the process proceeds to the next process.

In addition, you may comprise so that the specific game end determination processing of step 1500 may be performed, when No at step 1419-2.

With such a configuration, for example, in the case of ST100 times, when the ST100 fluctuation eye (displacement) is changing in one main game symbol, the 101 fluctuation eye in the other main gaming symbol starts to change. Can be drawn with a low probability.

Next, FIG. 36 is a flowchart of the other main game variation control process according to the subroutine of step 3350 in FIG. This process is executed when the stopped main game symbol is a big hit symbol or a small hit symbol. First, the CPUMC of the main control board M refers to the first and second main game symbol information temporary storage means, and determines whether or not the stopped main game symbol is the first main game symbol. If Yes in step 3352, in step 3354, the CPUMC of the main control board M refers to the first and second main game symbol information temporary storage means to determine whether or not the second main game symbol is changing. To do. If Yes in step 3354, in step 3356, the CPU MC of the main control board M forcibly stops the changing second main game symbol due to a loss, and proceeds to the next process (process of step 1500). On the other hand, if No in step 3352, in step 3358, the CPUMC of the main control board M refers to the first and second main game symbol information temporary storage means, and is the first main game symbol changing? Determine whether or not. If Yes in step 3358, in step 3359-1, the CPU MC of the main control board M determines whether or not the stop symbol is the small hit symbol. If Yes in step 3359-1, in step 3360, the CPU MC of the main control board M temporarily stops the changing first main game symbol, and proceeds to the next process (process of step 1500). On the other hand, in the case of No in step 3359-1 (=when the stop symbol is a big hit symbol), the first main game symbol in the fluctuation is forcibly stopped by a loss, and the process proceeds to the next process (process of step 1500). .. Even if No in step 3354 or step 3358, the process proceeds to the next process (process in step 1500). Incidentally, the fluctuation of the temporarily stopped first main game symbol is configured to restart the fluctuation after the end of the small hit related to the stopped second main game symbol, and the fluctuation of the first main game symbol is restarted. It is configured to stop on the basis of the win/no win lottery result and the symbol lottery result drawn before the start of variation. With this configuration, if the second main game symbol is changing when the first main game jackpot symbol is stopped in the non-time-reduced game state (low base state), if the second main game symbol is changing The fluctuation time of the 2 main game symbols is a long time, and since the big hit related to the 2nd main game symbol should not be executed, the 2nd main game symbol in the fluctuation is forcibly stopped by a loss, and the non-time is shortened. If the first main game symbol is fluctuating when the second main game small hit symbol is stopped in the gaming state, the fluctuating first main game symbol will be temporarily stopped.

Next, FIG. 37 is a flowchart of the specific game end determination processing according to the subroutine of step 1500 in FIG. First, in step 1502, the CPU MC of the main control board M refers to the probability variation counter and determines whether or not the counter value is greater than zero. If Yes in step 1502, in step 1504, the CPU MC of the main control board M decrements the counter value of the probability variation counter. For example, when the probability variation continues substantially until the next big hit, the probability variation number counter is set to 10000 times and decremented by 1 for each variation. If Yes in step 1504, in step 1506, the CPU MC of the main control board M refers to the probability variation counter to determine whether the counter value is 0 or not. If Yes in step 1506, in step 1508, the CPU MC of the main control board M turns off the main game probability variation flag, and proceeds to step 1510. Even if No in step 1502 or step 1506, the process proceeds to step 1510.

Next, in step 1510, the CPUMC of the main control board M refers to the hour/hour counter and determines whether or not the counter value is greater than zero. If Yes in step 1510, in step 1512, the CPUMC of the main control board M decrements the counter value of the time saving counter by 1. Next, in step 1514, the CPU MC of the main control board M refers to the hour/hour counter and determines whether or not the counter value is 0. If Yes in step 1514, in step 1516, the CPU MC of the main control board M turns off the main game time saving flag. Next, in step 1518, the CPU MC of the main control board M turns off the auxiliary game time saving flag and shifts to the next processing. Even if No in step 1510 or step 1514, the process proceeds to the next process. As described above, the main game time saving flag is divided into a plurality of types based on a combination of ON or OFF of two flags of the main game probability change flag and the auxiliary game time saving flag, and the target main game symbol is changed. In this case, the processing shown in step 1516 is not performed, and after the end of step 1518 (or in the case of No in step 1510 or in the case of No in step 1514), the main game time saving is performed according to the result of checking both flags. You may comprise so that the type of flag may be changed or the process which changes the main game symbol used as the object of a main game shortening flag may be performed.

Next, FIG. 38 is a flowchart of the small hit game control process according to the subroutine of step 1700 in FIG. First, in step 1701, the CPUMC of the main control board M is a discharge waiting flag {a flag that is turned on in step 1722 described later, that is, a scheduled small hit game (particularly, the scheduled second big Whether the flag that is turned on during the discharge waiting period (discharge waiting time) of the game balls remaining in the second special winning opening C20} is off after the execution of the winning pattern C20 opening pattern) is completed. To judge. If Yes in step 1701, the CPU MC of the main control board M determines in step 1702 whether or not the small hit flag is on. If Yes in step 1702, in step 1704, the CPUMC of the main control board M turns off the small hit flag. Next, in step 1705, the CPUMC of the main control board M, the opening pattern of the second special winning opening C20 of the round (in this example, for example, in all the small hit symbols, "1.8 seconds open → close"). (In order to increase the expected value of the ball during a small hit due to the relationship between the game ball firing interval and the upstream winning opening, etc., it may be opened or closed multiple times with a short opening time and closing time, It is preferable to configure it so that the total opening time is within 1.8 seconds), and if the game ball continues to be fired toward the second big winning opening C20, the second big winning opening C20 Game balls are configured to enter multiple balls). The opening mode of the special winning opening (second special winning opening C20) at the time of executing the small hit can be arbitrarily set. For example, the total opening time of the second special winning opening C20 at the time of executing the small hit once. May be appropriately configured to be a predetermined time or less (for example, 1.8 seconds or less). Next, in step 1706, the CPUMC of the main control board M turns on the small hit execution flag. Next, in step 1707, the CPUMC of the main control board M issues a small hit execution start command (a command to the effect that the small hit game has been started, and launches a game ball toward the second special winning opening C20 to the player. Is set in a command transmission buffer for transmission to the sub-main control unit SM (transmitted to the sub-main control unit SM side by the control command transmission process in step 1999). Next, in step 1708, the CPU MC of the main control board M opens the second special winning opening C20 and starts the small hitting game timer (the timer value is counted down). Next, in step 1709, the CPUMC of the main control board M starts the discharge standby timer (increment timer), and proceeds to step 1712. In addition, the discharge standby timer is configured to end the discharge standby time after a predetermined time has elapsed from the start of the small hit by measuring the elapsed time from the start of the small hit game (of course, the measurement of the discharge standby time The method is not limited to this, and for example, the measurement may be started after the completion of the scheduled small hit game (particularly, the scheduled opening pattern of the second special winning opening C20)}.

On the other hand, if No in step 1702, in step 1710, the CPU MC of the main control board M determines whether or not the small hit execution flag is on. If Yes in step 1710, the process moves to step 1712.

Next, in step 1712, the CPU MC of the main control board M determines whether or not there is a game ball winning (ball winning) in the second special winning opening C20. If Yes in step 1712, in step 1714, the CPUMC of the main control board M determines whether or not there is a predetermined number (for example, 3) of winning balls in the second special winning opening C20. If Yes in step 1714, the process moves to step 1718. On the other hand, in the case of No in step 1712 or step 1714, in step 1716, the CPU MC of the main control board M refers to the small hit game timer to determine whether or not a predetermined time period related to opening of the special winning opening has passed. .. If Yes in step 1716, the process moves to step 1718.

Next, in step 1718, the CPU MC of the main control board M stops driving the second special winning opening electric prize C21d and closes the second special winning opening C20. Next, in step 1722, the CPUMC of the main control board M turns on the discharge standby flag (the discharge standby time is started from the timing of executing this processing), and the process proceeds to step 1724. Even if No in step 1701, the process moves to step 1724.

Next, in step 1724, the CPUMC of the main control board M determines whether or not the timer value has reached the discharge standby time end value. If Yes in step 1724, the CPU MC of the main control board M clears the discharge standby timer to zero in step 1725. Next, in step 1726, the CPUMC of the main control board M turns off the discharge standby flag. Next, in step 1728, the CPU MC of the main control board M stops and resets the small hitting game timer. Next, in step 1730, the CPUMC of the main control board M turns off the small hit execution flag, and proceeds to the next process. In addition, also in the case of No in step 1710, step 1716, or step 1724, the process proceeds to the next process.

Here, in this example, the maximum number of winnings set as a program in one small hit is 3, and the maximum opening time of the big winning opening in one small hit is 1.8 seconds or less (more specifically Specifically, the opening mode of the special winning opening when a small hit is performed once is set to "a series of opening/closing operations of opening for 1.8 seconds and closing", and either closing condition is achieved. It is controlled so that the special winning opening is closed. Here, in order to suppress excessive winning and minimize the deviation from the payout design value, it is desirable to control so as to close immediately after the closing condition is achieved. On the other hand, even if such a treatment is performed, a ball has entered the special winning opening immediately after the closing condition has been achieved, or a prize-winning ball has accumulated in front of the count sensor (the count sensor detects the prize-winning ball after the closure condition is achieved. It is also possible. Therefore, regardless of whether the maximum opening time has elapsed or the maximum number of winnings has been exceeded, the winnings are processed as valid winnings only under predetermined conditions (within a predetermined period after closing). It is desirable to do.

Next, FIG. 39 is a flowchart of the special game control processing relating to the subroutine of step 1600 in FIG. First, in step 1602, the CPU MC of the main control board M determines whether or not the special game shift permission flag is on. If Yes in step 1602, in steps 1604 and 1606, the CPU MC of the main control board M turns off the special game transition permission flag and turns on the special game execution flag. Next, in step 1607, the CPU MC of the main control board M sets an initial value (1 in this example) to a round number counter (not shown). Next, in step 1608, the CPUMC of the main control board M sets information (special game start display instruction command) indicating that the special game is started in the command transmission buffer for transmitting to the sub-main control unit side ( In the control command transmission process of step 1999, the control command is transmitted to the sub-main controller SM side), and the process proceeds to step 1612.

On the other hand, if No in step 1602, in step 1610, the CPU MC of the main control board M determines whether or not the special game execution flag is on. Then, if Yes in step 1610, the process moves to step 1612. Incidentally, in the case of No in step 1610, the CPUMC of the main control board M determines that the special game is not permitted, and shifts to the next process (the process of step 1601).

Next, at step 1612, the CPUMC of the main control board M determines whether or not the round continuation flag is off, in other words, immediately before the start of each round. If Yes in step 1612, that is, immediately before the start of each round, first, in step 1614, the CPUMC of the main control board M first sets the open pattern (for example, the open pattern that continues to open, the pattern that opens and closes). Set. Next, in step 1616, the CPUMC of the main control board M clears the prize ball counter value to zero. Next, in step 1618, the CPUMC of the main control board M turns on the round continuation flag. Next, in step 1620, the CPU MC of the main control board M drives the first special winning opening electric winning combination C11d (or the second special winning opening electric winning combination C21d) to drive the first special winning opening C10 (or second The special winning opening C20) is opened, and the special game timer (especially the opening time timer) is set to a predetermined time (for example, the first special winning opening: 30 seconds, the second special winning opening: 1.8 seconds) and the start is started. , And proceeds to step 1622. On the other hand, if No in step 1612, that is, if the first special winning opening C10 (or the second special winning opening C20) is open, the process proceeds to step 1622 without performing the processing of steps 1614 to 1620.

Next, in step 1622, the CPU MC of the main control board M transmits a game state command related to the current special game (for example, the current number of rounds or the number of winning game balls) to the sub-main control unit SM side. To the command transmission buffer for transmission (in the control command transmission process of step 1999, the data is transmitted to the sub-main control unit SM side). Next, in step 1624, the CPUMC of the main control board M refers to the counter value of the winning ball counter, and determines the predetermined number (for example, the first winning port C20) of the first winning port C10 (or the second winning port C20) in the round. It is determined whether or not there is a winning ball of 10 coins in the second prize hole and 3 coins in the second prize hole. If Yes in step 1624, the process moves to step 1628. On the other hand, in the case of No in step 1624, in step 1626, the CPU MC of the main control board M refers to the special game timer (especially the opening time timer) to determine the predetermined time (eg, the first prize) Mouth: 30 seconds, second special winning opening: 1.8 seconds) is determined. If Yes at step 1626, the process proceeds to step 1628. When the result in step 1626 is No, the process moves to the next process (process in step 1601).

Next, in step 1628, the CPUMC of the main control board M stops driving the first special winning opening electric winning combination C11d (or the second special winning opening electric winning combination C21d), and then the first special winning opening C10 (or The second big winning opening C20) is closed. Next, in step 1630, the CPU MC of the main control board M resets the special game timer (in particular, the open time timer). Next, in step 1632, the CPUMC of the main control board M turns off the round continuation flag. Next, in step 1633, the CPUMC of the main control board M adds 1 to the counter value of the round number counter (not shown). Next, in step 1634, the CPUMC of the main control board M determines whether or not the final round has ended (for example, the counter value of the round number counter (not shown) in the special game-related information temporary storage means indicates the maximum number of rounds). It is judged whether it exceeded. If Yes in step 1634, in step 1636, the CPU MC of the main control board M turns off the special game execution flag. Next, in step 1638, the CPU MC of the main control board M sets the information (special game end display instruction command) indicating that the special game is to be ended in the command transmission buffer for transmitting to the sub-main control section SM side. (Transmitted to the sub-main control unit SM side in the control command transmission process of step 1999). Then, in step 1650, the CPU MC of the main control board M executes a game state determination process after completion of a special game described later, and shifts to the next process (process of step 1601). Even if No in step 1634, the process proceeds to the next process (process in step 1601).

Next, FIG. 40 is a flowchart of the game state determination processing after the end of the special game according to the subroutine of step 1650 in FIG. First, in step 1651, it is determined whether or not the stopped symbol is a symbol that is a probability variation game. If Yes in step 1651, in step 1652, the CPU MC of the main control board M sets a certain number of times (10,000 times in this example) in the probability variation counter. Next, in step 1654, the CPUMC of the main control board M turns on the main game probability variation flag. On the other hand, if No in step 1651, the process moves to step 1655.

Next, in step 1655, it is determined whether or not the stopped symbol is a symbol which is a time-saving game (high base). If Yes in step 1655, in step 1656, the specific game control means MP50 sets a predetermined number of times (30, 60, 10000 times, etc.) in the time saving counter. Next, in step 1658, the CPUMC of the main control board M turns on the main game time saving flag. Next, in step 1660, the CPU MC of the main control board M turns on the auxiliary game time saving flag and shifts to the next processing (processing of step 1601). As described above, in order to make the main game shorter time flag different depending on the combination of other flags (main game probability change flag, auxiliary game shorter time flag), or to switch the target main game according to the game state, The content of the data set in the main game shortened flag may be switched according to the type of winning. For example, the 1-byte data configured as the main game short-time flag is provided with a bit that is turned on when the main game probability variation flag is on and a bit that is turned on when the auxiliary game short-time flag is on, The control contents of the time saving game state (auxiliary game state) may be made different depending on whether the two bits are “0” or “1”.

Next, FIG. 41 is a flowchart of the special game operating condition determination processing relating to the subroutine of step 1550 in FIG. First, in step 1552, the CPUMC of the main control board M determines whether or not the condition device operation flag is ON. If Yes in step 1552, in step 1554, the CPU MC of the main control board M turns off the specific game flag (main game probability change flag/main game shortened flag). Next, in step 1556, the CPUMC of the main control board M clears the value of the probability variation counter. Next, in step 1558, the CPUMC of the main control board M clears the value of the hour/hour counter. Next, in step 1564, the CPUMC of the main control board M turns on the special game shift permission flag. Next, in step 1566, the CPUMC of the main control board M turns off the condition device operation flag, and proceeds to the next processing (processing of step 1550-1). Even if No in step 1552, the process proceeds to the next process (process of step 1550-1).

Next, FIG. 42 is a flowchart of the fraud detection information management process according to the subroutine of step 1900 in FIG. First, in step 1902, the CPU MC of the main control board M refers to the illegal radio wave sensor and determines whether or not the input from the illegal radio wave sensor is continuously ON a predetermined number of times (for example, the process is a timer interrupt process). The process is executed in step S6, and it is intended to remove the influence of noise by determining whether or not it is continuously turned ON at a predetermined number of interrupts. In the case of "a predetermined number of times consecutively", it has the same meaning). If Yes in step 1902, in step 1904, the CPU MC of the main control board M determines that an illegal radio wave has been detected, turns on the illegal radio wave detection flag, and proceeds to step 1912. On the other hand, if No in step 1902, in step 1906, the CPU MC of the main control board M refers to the illegal radio wave sensor and determines whether the input from the illegal radio wave sensor is OFF for a predetermined number of times in succession. In the case of Yes in step 1906, in step 1908, the CPUMC of the main control board M determines that the detection of the illegal radio wave is completed, turns off the illegal radio wave detection flag, and proceeds to step 1912. Even if No in step 1906, the process proceeds to step 1912.

Next, in step 1912, the CPU MC of the main control board M refers to the illegal magnetic sensor and determines whether or not the input from the illegal magnetic sensor is continuously ON a predetermined number of times. If Yes in step 1912, in step 1914, the CPUMC of the main control board M determines that illegal magnetism is detected, turns on the illegal magnetism detection flag, and proceeds to step 1922. On the other hand, in the case of No in step 1912, in step 1916, the CPU MC of the main control board M refers to the illegal magnetic sensor and determines whether the input from the illegal magnetic sensor is OFF for a predetermined number of times in succession. In the case of Yes in step 1916, in step 1918, the CPU MC of the main control board M determines that the detection of the illegal magnetism is completed, turns off the illegal magnetism detection flag, and proceeds to step 1922. Even if No in step 1916, the process proceeds to step 1922.

Next, in step 1922, the CPU MC of the main control board M refers to the door opening sensor and determines whether or not the input from the door opening sensor is continuously ON a predetermined number of times. If Yes in step 1922, in step 1924, the CPU MC of the main control board M determines that the door unit D18 has been opened, turns on the door opening flag, and proceeds to step 1932. On the other hand, if No in step 1922, in step 1926 the CPU MC of the main control board M refers to the door opening sensor and determines whether the input from the door opening sensor is OFF for a predetermined number of times in succession. If Yes in step 1926, in step 1928 the CPUMC of the main control board M determines that the door unit D18 has been opened, turns off the door opening flag, and proceeds to step 1932. Even if No in step 1926, the process proceeds to step 1932.

Next, in step 1932, the CPU MC of the main control board M refers to the frame opening sensor and determines whether or not the input from the frame opening sensor is continuously ON a predetermined number of times. If Yes in step 1932, in step 1934, the CPU MC of the main control board M determines that the gaming machine frame D has been opened, turns on the frame opening flag, and proceeds to step 1934. On the other hand, if No in step 1932, in step 1936, the CPU MC of the main control board M refers to the frame opening sensor and determines whether the input from the frame opening sensor is OFF for a predetermined number of times in succession. If Yes in step 1936, in step 1938, the CPU MC of the main control board M determines that the gaming machine frame D has been opened, turns off the frame opening flag, and proceeds to the next process (process of step 1950). .. Even if No in step 1936, the process proceeds to the next process (process of step 1950).

Next, FIG. 43 is a flowchart of the error management process related to the subroutine of step 1950 in FIG. First, in step 1952, the CPUMC of the main control board M determines whether or not the error occurrence condition is satisfied. If Yes in step 1952, in step 1954, the CPUMC of the main control board M transmits a command (command to the sub control board S side) related to the fact that an error has occurred and error type information (control command of step 1999). It is transmitted to the sub-main control unit SM side by the transmission process). Next, in step 1956, the CPUMC of the main control board M determines whether or not the error cancellation condition is satisfied. If Yes in step 1956, in step 1958, the CPUMC of the main control board M transmits a command (command to the sub control board S side) related to the information indicating that the error is released (control command transmission process of step 1999). Is transmitted to the sub-main control unit SM side by), and the process proceeds to the next process (process of step 1550-7). Even if No in step 1952 or step 1956, the process moves to the next process (process in step 1550-7).

Next, FIG. 44 is a flowchart of the firing control signal output process according to the subroutine of step 1550-7 in FIG. First, in step 1550-7-1, the CPUMC of the main control board M indicates a payout control board (sometimes referred to as a prize ball payout control board KH), a communication state (BIT0), and a disconnection short-circuit power supply abnormality (BIT1). Get the error flag. BIT0 indicating the communication status indicates normal if "00000000B" and abnormal if "00000001B". In BIT1 indicating a disconnection short circuit power supply abnormality, "00000000B" indicates normality, and "00000010B" indicates abnormality. Next, in step 1550-7-2, the CPUMC of the main control board M calculates the logical product of the error flag acquired in step 1550-7-1 and the determination data (“00000011B”). Next, in step 1550-7-3, the CPUMC of the main control board M sets the firing permission signal bit data. For example, BIT5 of the output port indicates a firing permission signal, and "00000000B" indicates an error (abnormal) and "0010000B" indicates normal. Next, in step 1550-7-4, the CPUMC of the main control board M outputs to the output port and shifts to the next processing (processing of step 1550-8). Here, for the output port, for example, BIT0 is digit 1-bit data, BIT1 is digit 2-bit data, BIT2 is digit 3-bit data, BIT3 is digit 4-bit data, BIT4 is digit 5-bit data, and BIT5 is firing enable signal bit data. , BIT6 is configured as effect strobe bit data, and BIT7 is configured as security bit.

Next, FIG. 45 is a flowchart of the external signal output processing according to the subroutine of step 3500 in FIG. First, in step 3502, the CPU MC of the main control board M refers to the game state temporary storage means to confirm the state of the game machine. Next, in step 3504, the CPU MC of the main control board M outputs a signal indicating the state of the gaming machine to the hall computer HC via the external relay terminal board G based on the confirmed state of the gaming machine, and then Processing (step 1550-11 processing).

(External relay terminal board)
Here, the signal output through the external relay terminal board G according to the present embodiment will be described with reference to the lower part of the figure (image diagram of signal output). On the external relay terminal board G, a plurality of external connection terminals as output terminal parts to which various cable connectors are connected {for example, information on prize ball payout, information on winning or winning of symbols, current game state (normal state, specific Gaming status information output terminal for outputting information about gaming status, special gaming status, etc., error information output for outputting various error information detected by opening detection sensor etc. when the door is open Terminals, etc.} are provided. Then, as will be described later, the plurality of output terminals are configured to be capable of outputting information from the plurality of output terminals to the hall computer HC by being connected to the hall computer HC by a cable harness. Here, in the present embodiment, one output terminal is assigned as an output terminal of the payout related information which is information output from the prize ball payout control board KH and is a plurality of types of information. The output terminals other than the one output terminal are terminals for outputting signals output from the main control board M. For example, a jackpot output terminal that outputs a signal during a jackpot during jackpot (there are a plurality of jacks depending on the type of jackpot). ), a door opening output terminal that outputs a signal while the glass door D18 is open, a starting opening winning time output terminal that outputs a signal when the winning opening is won, and there is not enough balls in the prize ball tank KT. While the output terminal for outputting the signal while the ball is running, the output terminal for the number of special symbol confirmation times that outputs the signal when the special symbol confirmation stop, etc. of the game related information that is important information for the game hall operator side It is an output terminal. That is, by using the output terminal of the payout related information as one output terminal, it is possible to avoid exhaustion of the output terminals of these important game related information.

Further, in the present embodiment, the main control board M and the prize ball payout control board KH are configured to send the game related information and the payout related information to the external relay terminal board G in the form of one-way serial transmission. There is. That is, no transmission line is provided from the external relay terminal board G to the main control board M and the prize ball payout control board KH (the same applies to information transmission from the external relay terminal board G to the hall computer HC).

Here, the outline of the information transmission system of the pachinko gaming machine according to the present embodiment will be described. First, between the main control board M and the prize ball payout control board KH and the external relay terminal board G, and the external relay terminal board. The G and the hall computer HC are connected by a cable harness. On the other hand, as shown in this example, since the external relay terminal board G is constituted by a communication relay (so-called relay), the main control board M, the prize ball payout control board KH, and the hall computer HC are always in conduction. It does not mean that That is, an electrical signal (a binary logic signal whose voltage is Hi level/Low level) input from the main control board M and the prize ball payout control board KH to the input terminal of the external relay terminal board G is the relay. After being replaced by a physical signal (a binary logic signal whose switch state is ON/OFF) by the section, the signal is output from the output terminal of the external relay terminal board G to the hall computer HC. More specifically, the external relay terminal board G has a plurality of relay coils G1 and contact portions G2 corresponding to the respective input/output terminals. Then, when the relay coil G1 is excited based on the pulse signal input to the input terminal, a magnetic force is generated, and the generated magnetic force causes the contact portion G2 to be closed, so that the output terminal and the hall computer HC are electrically connected. Further, when the relay coil G1 is demagnetized, the contact portion G2 returns to the open state, so that the output terminal and the hall computer HC are not electrically connected. Therefore, on the side of the hall computer HC, it is possible to obtain a pulse signal substantially the same as the pulse signal input to the input terminal of the external relay terminal board G by detecting the conducting period. With such a configuration, it is possible to physically secure one-way communication from the main control board M and the prize-ball payout control board KH to the hall computer HC, and the hall computer HC side main control board M and This prevents a goto action (so-called remote operation goto) that illegally operates the prize ball payout control board KH. In this example, the mechanism using the relay coil is configured to enable the one-way communication to the hall computer HC while preventing the goto action. However, the invention is not limited to this, and for example, a pair of light emitting units and One-way communication is also possible by a photo sensor having a light receiving section (for example, light from a light emitting section connected to the main control board M and the prize ball payout control board KH is received by a hall computer HC). It is possible to receive the signal by reading the section).

However, since the physical signal (switch state is turned on/off) is once replaced, the main control board M and the prize-ball payout control board KH are connected to the hall computer HC by one of the external relay terminal boards G. It is difficult to transmit complicated information using the input/output terminal, and one type of information is transmitted using the one input/output terminal (for example, if it is an output terminal for the special symbol determination frequency, It is customary to configure such that only the information indicating that "1 variation of the special symbol has ended" can be transmitted).

Next, the processing on the prize ball payout control board KH side will be described in detail with reference to the flowcharts of FIGS. 46 to 57.

First, FIG. 46 is a flowchart of the main routine 4000 executed on the prize ball payout control board KH side. First, in step 4100, the payout control board (payout control means) KH executes an error detection error control process described later. Next, in step 4200, the payout control board (payout control means) KH executes a prize ball payout related information transmission/reception process to be described later with the main control board M. Next, at step 4300, the payout control board (payout control means) KH executes a prize ball payout control process (prize ball payout start/motor drive start) described later. Next, at step 4400, the payout control board (payout control means) KH executes a prize ball payout control process (at the end of motor driving/at the end of prize ball payout) which will be described later. Next, in step 4500, the payout control board (payout control means) KH executes a prize ball payout control process (when the motor is driven) which will be described later. Then, in step 4600, the payout control board (payout control means) KH executes a later-described motor error time process, and proceeds to step 4100.

Here, with reference to the block diagram on the right side of the figure, the prize-ball payout control board KH of the gaming machine in the present embodiment controls transmission/reception of commands/information with the main control board M side, the card unit R side, and the like. A transmission/reception control means 3100 for controlling, an error control means 3200 for controlling an error related to payout on the prize ball payout control board KH side, and a predetermined number of game balls upon receiving a prize ball payout command or a ball rental command. And a payout control unit 3300 that executes the payout process. Hereinafter, each means will be described in detail.

First, the transmission/reception control unit 3100 receives the information (for example, a command or a signal) from the main control board M or the card unit R and controls the reception control unit 3110, and transmits the information to the main control board M or the card unit R. And a transmission control unit 3120 that controls the control.

Here, the reception control unit 3110 further includes a main-side reception control unit 3111 that controls reception of information (for example, a command) from the main control board M. The main-side reception control means 3111 further includes a main-side reception information temporary storage means 3111a in which the information transmitted from the main control board M side is temporarily stored. Further, the transmission control means 3120 further has a payout-related error information temporary storage means 3121 in which error information relating to a payout operation for transmission to the main control board M side is temporarily stored.

Next, the error control means 3200 detects an abnormal operation of the payout motor and an error flag temporary storage means 3221 for temporarily storing the on/off state of an error flag such as payout on the prize ball payout control board KH side. Error control means 3230 at the time of detection of a payout motor operation abnormality, which controls error control at the time, error control means 3240 at the time of detection of a payout abnormality, which controls error control when a payout abnormality is detected, and error when a ball path abnormality is detected Error control means 3250 at the time of detecting a ball path abnormality that controls the control, error control means 3260 at the time of detecting a payout motor abnormality that controls the error control when a payout motor abnormality is detected, and a fatal abnormality related to the prize ball payout operation are detected. A pay-out stop abnormality detection error control means 3270 that controls error control when a ball-clogging error occurs, and a ball-clogging error occurrence timer 3200t that manages the error notification period when a ball-clogging error occurs in the prize ball payout unit KE10. The payout count sensor KE10s further includes a non-passing error occurrence timer 3200t2 that manages the error notification period when a non-passing error occurs. Here, the payout motor operation abnormality detection error control unit 3230 further has an illegal payout accumulation counter 3231 for accumulating and counting the number of times the payout motor operation abnormality is detected. Further, the payout abnormality detection error control means 3240 further has an excess payout accumulation counter 3241 for accumulating and counting the number of payouts of excessive prize balls. Further, the ball path abnormality detection error control means 3250 further has a payout interval extension control means 3251 for executing time extension processing of the payout interval relating to prize ball payout. Further, the payout motor abnormality detection error control means 3260 further includes a retry operation control means 3261 for executing a retry operation (retry operation) for eliminating the abnormal operation of the payout motor KE10m.

Next, the payout control unit 3300 has a payout process related information temporary storage unit 3310 for temporarily storing information necessary for the payout process. Here, the payout process related information temporary storage unit 3310 temporarily stores a payout state flag temporary storage unit 3311 for temporarily storing a state related to payout (for example, whether or not a payout is in progress and whether or not a payout abnormality has occurred). At the time of payout processing, the payout counter 3312 in which the number of game balls to be paid out is set, the step counter temporary storage means 3313 for temporarily storing the number of steps to be driven of the payout motor KE10m, and the payout motor KE10m are driven. In this case, the excited stator position specifying counter value temporary storage means 3314 for temporarily storing the position information of the excited stator and a predetermined time (waiting for ball passage) after one continuous payout operation (unit payout operation) It further has a ball passage waiting timer 3315 for measuring time/motor pause time) and a unit payout counter 3317 in which the number of game balls to be paid out by the unit payout operation is set. Here, in the present embodiment, the ball passage waiting timer 3315 is a decrement type timer and is configured to stop when the timer value becomes 0, but the present invention is not limited to this, and is an increment type timer. It is also possible to use a timer. Hereinafter, each subroutine will be described in detail.

Next, FIG. 47 is a flowchart of the error control processing at the time of abnormality according to the subroutine of step 4100 of FIG. First, in step 4110, the error control unit 3200 executes a payout motor operation abnormality detection error control process described later. Next, in step 4120, the error control unit 3200 executes a payout abnormality detection error control process described later. Next, in step 4140, the error control means 3200 executes a ball path abnormality detection error control process described later. Next, in step 4170, the error control means 3200 executes a payout motor abnormality detection error control process described later. Next, in step 4190, the error control means 3200 executes an after-payment stop abnormality detection error control process, which will be described later, and shifts to the next process (prize ball payout related information transmission/reception process in step 4200).

Next, FIG. 48 is a flowchart of the payout motor operation abnormality detection error control processing according to the subroutine of step 4110 of FIG. First, the purpose of this process is to count the number of times of occurrence of abnormality when a payout motor operation abnormality described later is detected, and to flag the occurrence of error when the number of occurrence of abnormality is equal to or greater than a threshold value. Is to turn on. First, in step 4111, the payout motor operation abnormality detection error control unit 3230 refers to the payout state flag temporary storage unit 3311 and determines whether or not the payout motor operation abnormality detection flag is ON. Here, as will be described later, the payout motor operation abnormality detection flag detects the passage of the game ball by the payout count sensor KE10s under the situation that the prize ball payout control board KH side is not executing the prize ball payout process. This is a flag that is turned on when the operation is performed (abnormality of payout motor operation). If Yes in step 4111, in step 4112, the payout motor operation abnormality detection error control means 3230 accesses the payout state flag temporary storage means 3311 and turns off the payout motor operation abnormality detection flag. Next, in step 4113, the payout motor operation abnormality detection error control means 3230 increments the counter value of the illegal payout accumulation counter 3231 by 1. Next, in step 4114, the payout motor operation abnormality detection error control means 3230 refers to the counter value of the illegal payout accumulation counter 3231 and determines whether or not the count value is a predetermined number (for example, 25) or more. To do. If Yes in step 4114, in step 4115 the payout motor operation abnormality detection error control means 3230 turns on the payout motor operation error flag in the error flag temporary storage means 3221, and proceeds to step 4116. Even if No in step 4111 or step 4114, the process proceeds to step 4116.

Next, in step 4116, the payout motor operation abnormality detection error control means 3230 refers to the error flag temporary storage means 3221 and determines whether or not the payout motor operation error flag is ON. If Yes in step 4116, in step 4119, the payout motor operation abnormality detection error control unit 3230 sets the payout motor operation error as the payout related error information in the payout related error information temporary storage unit 3121, and the next process ( The process proceeds to the payout abnormality detection error control process of step 4120). Even if No in step 4116, the process proceeds to the next process (error control process at the time of payout abnormality detection of step 4120).

Next, FIG. 49 is a flowchart of the payout abnormality detection error control processing according to the subroutine of step 4120 of FIG. First, the purpose of this process is to count the number of payouts of excessive game balls due to the abnormality when a payout abnormality described below is detected, and when the count is equal to or greater than a threshold value, This is to turn on the flag indicating that an error has occurred. First, in step 4121, the payout abnormality detection error control means 3240 refers to the payout state flag temporary storage means 3311 and determines whether or not the payout abnormality detection flag is ON. Here, as will be described later, when the payout abnormality detection flag exceeds a predetermined number of prize balls to be paid out based on a command transmitted from the main control board M side, and an excessive game ball payout is detected (payout) This is a flag that is turned on when (abnormal). If Yes in step 4121, in step 4122 the payout abnormality detection time error control means 3240 accesses the payout state flag temporary storage means 3311 and turns off the payout abnormality detection flag. Next, in step 4123, the payout abnormality detection error control means 3240 acquires the number of excess payouts temporarily stored in the payout process related information temporary storage means 3310, and stores the excess payout number in the excess payout cumulative counter 3241. to add. Next, in step 4124, the payout abnormality detection error control means 3240 refers to the counter value of the excessive payout accumulation counter 3241 and determines whether or not the count value is equal to or larger than a predetermined number (for example, 25). If Yes in step 4124, in step 4125, the payout abnormality detection error control means 3240 turns on the excessive payout error flag in the error flag temporary storage means 3221, and the process proceeds to step 4126. Even if No in step 4121 or step 4124, the process proceeds to step 4126. The overpayment error (state in which the overpayment error flag is on) is configured to be eliminated only by turning on the power again, but this example is merely an example, and the present invention is not limited to this. For example, the error may be eliminated by pressing an error release switch or when a predetermined time has elapsed.

Next, in step 4126, the payout abnormality detection error control means 3240 refers to the error flag temporary storage means 3221 and determines whether or not the excessive payout error flag is ON. If Yes in step 4126, in step 4129, the payout abnormality detection time error control means 3240 sets an overpayment error in the payout related error information temporary storage means 3121 as payout related error information, and the next process (step 4140). Error control processing at the time of detecting a ball path abnormality). Even if No in step 4126, the process proceeds to the next process (error control process at the time of ball path abnormality detection in step 4140).

Next, FIG. 50 is a flowchart of the ball path abnormality detection error control processing according to the subroutine of step 4140 of FIG. 47. First, the purpose of this processing is to detect an abnormality in a ball path, which will be described later, (1) Abnormality in which no game ball exists (ball out) in the prize ball tank KT or the prize ball payout unit KE10. Or, whether or not there is a small amount of game balls present in the prize ball payout unit KE10 (ball shortage) has occurred, and when an abnormality corresponding to the ball out abnormality or the ball shortage abnormality has been detected, , Turning on a flag indicating that an error has occurred. Further, (2) when an abnormality corresponding to an out-of-balls abnormality or an out-of-balls abnormality is detected, a waiting time until the out-of-balls abnormality or the out-of-balls abnormality is resolved by extending the payout interval of the prize ball payout. Is to produce. First, in step 4141, the ball path abnormality detection error control means 3250 refers to the payout state flag temporary storage means 3311 and determines whether or not the ball path abnormality detection flag is on. Here, as will be described later, the ball path abnormality detection flag indicates that the motor drive is operating normally when the predetermined number of payout operations (unit payout operations) are completed on the prize ball payout control board KH side. This flag is turned on when it is determined that the payout is less than the predetermined number under the situation determined to be paying. If Yes in step 4141, in step 4142 the ball path abnormality detection time error control means 3250 accesses the payout state flag temporary storage means 3311 and turns off the ball path abnormality detection flag. Next, in step 4143, the ball path abnormality detection error control means 3250 determines whether or not the conditions for occurrence of a ball out abnormality or a ball shortage abnormality are satisfied. Here, the occurrence condition of the ball out abnormality or the ball shortage abnormality is not particularly limited, but for example, a game ball detection sensor is provided at a predetermined position in the prize ball tank KT or the prize ball payout unit KE10, and the detection sensor is used. An example of a condition in which an out-of-balls abnormality occurs when the presence of a game ball cannot be detected, and a ball flow path immediately above the sprocket KE10p in the prize ball payout unit KE10 (in this example, two ball paths are There is an example in which a detection sensor for the game ball is provided for each of (presence), and when the presence of the game ball cannot be detected by any of the detection sensors, the condition of the ball shortage abnormality is occurring. If Yes in step 4143, in step 4144 the ball path abnormality detection error control means 3250 turns on the ball path error flag in the error flag temporary storage means 3221. Then, in step 4146, the ball path abnormality detection error control means 3250 sets the ball path error as the payout related error information in the payout related error information temporary storage means 3121, and proceeds to step 4151. Even if No in step 4141 or step 4143, the process proceeds to step 4151.

Next, in step 4151, the ball path abnormality detection error control means 3250 refers to the error flag temporary storage means 3221 and determines whether or not the ball path error flag is on. If Yes in step 4151, in step 4152 the ball path abnormality detection error control unit 3250 determines whether or not the condition for eliminating the ball out abnormality or the ball shortage abnormality is satisfied. Here, there is no particular limitation on the condition for eliminating the ball out abnormality or the ball shortage abnormality, and an example in which the abnormality is eliminated when the occurrence condition of the ball out abnormality or the ball shortage abnormality is unsatisfied Can be mentioned. If Yes in step 4152, in step 4153 the ball path abnormality detection error control means 3250 turns off the ball path error flag in the error flag temporary storage means 3221. Then, in step 4155, the payout interval extension control means 3251 causes the excitation timing during normal operation (for example, 3 ms×8 steps=24 ms to continuously excite a predetermined number of payout operations at one speed) and balls. A passage waiting time (for example, 500 ms) is set, and the process advances to the next process (error control process at the time of payout motor abnormality detection in step 4170). On the other hand, in the case of No in step 4152, in step 4156, the payout interval extension control means 3251 sets the excitation timing and the ball passage waiting time so that the payout speed of one ball becomes relatively slower than in the normal operation. After the change, the process proceeds to the next process (error control process at the time of detecting the payout motor abnormality in step 4170). Even if No in step 4151, the process proceeds to the next process (error control process at the time of payout motor abnormality detection in step 4170). Here, although the excitation timing to be changed is not particularly limited, for example, after performing a payout operation for one ball at a speed of 3 ms×8 steps=24 ms, waiting for a predetermined time (for example, 5 seconds) An example can be given in which the excitation timing is changed so that a payout operation is executed again at a speed of 3 ms×8 steps=24 ms after the waiting time has elapsed. Further, the sphere passage waiting time to be changed is not particularly limited (for example, changed from 500 ms to 30 seconds).

Next, FIG. 51 is a flowchart of the payout motor abnormality detection error control processing according to the subroutine of step 4170 of FIG. 47. First, the purpose of this process is to turn on a flag indicating the occurrence of an error and to retry the payout motor (the stepping motor KE10m in the prize ball payout unit KE10) when a payout motor abnormality described later is detected. It is to execute the switching control process. First, in step 4171, the payout motor abnormality detection time error control means 3260 refers to the payout state flag temporary storage means 3311, and determines whether or not the payout motor abnormality detection flag is ON. Here, as will be described later, the payout motor abnormality detection flag is a flag that is turned on when it is determined that the motor drive is not normally operating due to an external factor such as a ball entrainment. If Yes in step 4171, in step 4172 the payout motor abnormality detection time error control means 3260 turns off the payout motor abnormality detection flag in the payout state flag temporary storage means 3311. Next, at step 4173, the payout motor abnormality detection error control means 3260 turns on the payout motor error flag in the error flag temporary storage means 3221. Next, at step 4175, the payout motor abnormality detection error control means 3260 sets a payout motor error as payout related error information in the payout related error information temporary storage means 3121. Then, in step 4176, the payout motor abnormality detection error control means 3260 turns on the retry operation execution standby flag in the payout state flag temporary storage means 3311, and proceeds to step 4177. Even if No in step 4171, the process proceeds to step 4177. Here, the retry operation execution standby flag is a flag for setting the retry operation in a standby state for a predetermined time after the occurrence of a motor error, which will be described later, and for providing a motor error elimination waiting time within the predetermined time.

Next, in step 4177, the payout motor abnormality detection error control means 3260 refers to the error flag temporary storage means 3221 and determines whether or not the payout motor error flag is on. If Yes in step 4177, in step 4178, the retry operation control unit 3261 refers to the payout state flag temporary storage unit 3311 and determines whether or not the retry operation execution permission flag is on. If Yes in step 4178, the retry operation control unit 3261 turns off the retry operation execution permission flag in the payout state flag temporary storage unit 3311 in step 4179. Next, in step 4180, the retry operation control means 3261 sets a predetermined number of steps during the retry operation as the step counter value (n) in the step counter temporary storage means 3313. Here, the predetermined number of steps in the retry operation is not particularly limited, but an example in which it is the same as the confirmation timing of the rotor position confirmation sensor KE10ms in the retry operation described later can be given. Next, at step 4181, the retry operation control means 3261 sets 0 as the excitation stator position identification counter value (j) in the excitation stator position identification counter value temporary storage means 3314. Next, in step 4182, the retry operation control unit 3261 causes the excitation method for the retry operation related to the stepping motor operation (for example, the well-known 1-2 phase excitation method) and the one-step switching speed for the retry operation (for example, 6 ms). Next, in step 4183, the retry operation control means 3261 sets a predetermined value (for example, 500 ms) as the ball passing waiting time/motor pause time related to the stepping motor operation in the ball passing waiting timer 3315. Next, in step 4184, the retry operation control means 3261 turns on the retry operation executing flag in the payout state flag temporary storage means 3311. Then, in step 4185, the retry operation control means 3261 turns on the motor driving flag in the payout state flag temporary storage means 3311, and shifts to the next processing (error control processing at the time of payout stop abnormality detection in step 4190). To do. Even if No in step 4177 or step 4178, the process shifts to the next process (error control process at the time of detection of payout stop abnormality in step 4190).

Next, FIG. 52 is a flowchart of the payout stop abnormality detection error control process according to the subroutine of step 4190 of FIG. 47. First, the purpose of this process is to turn on the flag indicating the occurrence of an error when a fatal abnormality related to the continuation of the prize ball payout process is detected, and to fatally affect the continuation of the prize ball payout process. It is impossible to continue the prize ball payout process until the abnormality is resolved. Here, the fatal abnormality relating to the continuation of the prize-ball payout process is a communication abnormality between the main control board M and the prize-ball payout control board KH, a communication abnormality between the card unit R and the prize-ball payout control board KH, and payout. Examples include a sensor abnormality of the count sensor KE10s, a tray (upper plate) full tank abnormality, and the like. First, in step 4191-1, the payout stop abnormality detection error control means 3270 refers to the error flag temporary storage means 3221 and determines whether or not the payout motor error flag is switched from off to on. If Yes in step 4191-1, in step 4191-2, the payout stop abnormality detection error control unit 3270 sets the error duration time (for example, 120 seconds) to the ball biting error occurrence timer 3200t and starts the operation. The procedure moves to Step 4192-1. On the other hand, in the case of No in step 4191-1, in step 4191-3, the payout stop abnormality detection time error control means 3270 refers to the ball biting error occurrence timer 3200t to determine whether or not the timer value is 0. judge. If Yes in step 4191-3, in step 4191-4, the payout stop abnormality detection error control means 3270 turns off the payout motor error flag in the error flag temporary storage means 3221, and proceeds to step 4192-1. Transition. On the other hand, if No in step 4191-3, the process moves to step 4192-1.

Next, in step 4192-1, the payout stop abnormality detection error control unit 3270 refers to the error flag temporary storage unit 3221 and determines whether or not the switch non-passage error detection flag is switched from OFF to ON. If Yes in step 4192-1, in step 4192-2, the payout stop abnormality detection error control unit 3270 sets the error continuation time (for example, 120 seconds) to the non-passing error occurrence timer 3200t2, and starts the operation. The procedure moves to Step 4193-1. On the other hand, in the case of No in step 4192-1, in step 4192-3, the payout stop abnormality detection time error control means 3270 refers to the non-passing error occurrence timer 3200t2 to determine whether or not the timer value is 0. judge. If Yes in step 4192-3, in step 4192-4, the payout stop abnormality detection error control unit 3270 turns off the switch non-passage error flag in the error flag temporary storage unit 3221, and then in step 4193-1. Move to. On the other hand, if No in step 4192-3, the process moves to step 4193-1.

Next, in step 4193-1, the payout stop abnormality detection error control means 3270 determines whether or not the error release switch KH3a is pressed. In the case of Yes in step 4193-1, in step 4193-2 to step 4193-5, the payout stop abnormality detection error control unit 3270 has a flag relating to an error including pressing of the error canceling switch KH3a as an error canceling condition ( For example, the payout motor operation error flag, the payout operation incomplete game ball detection flag, the payout motor error flag, the switch non-passage error detection flag) are turned off, and the process proceeds to step 41944-1. On the other hand, if No in step 4193-1, the process proceeds to step 4194-1.

Next, at step 4194-1, the payout stop abnormality detection error control means 3270 determines whether or not a communication abnormality between the main control board M and the prize ball payout control board KH is detected. If Yes in step 4194-1, in step 4194-2, the payout stop abnormality detection error control means 3270 turns on the communication error flag in the error flag temporary storage means 3221 and proceeds to step 4195-1. .. On the other hand, if No in step 4194-1, in step 4194-3, the payout stop abnormality detection error control unit 3270 turns off the communication error flag in the error flag temporary storage unit 3221, and proceeds to step 4195-1. Transition.

Next, in step 4195-1, the payout stop abnormality detection error control unit 3270 causes the sensor abnormality of the payout count sensor KE10s (for example, no input from the count sensor or a constant input value for a predetermined time or more). Yes, etc.) is detected. If Yes in step 4195-1, in step 4195-2, the payout stop abnormality detection error control means 3270 turns on the prize ball device error flag in the error flag temporary storage means 3221, and proceeds to step 4196-1. Transition. On the other hand, if No in step 4195-1, in step 4195-3, the payout stop abnormality detection error control means 3270 turns off the prize ball device error flag in the error flag temporary storage means 3221, and the step 4196- Move to 1.

Next, at step 4196-1, the pay-out stop abnormality detection error control means 3270 determines whether or not a tray (upper plate) full tank abnormality is detected. If Yes in step 4196-1, in step 4196-2, the payout stop abnormality detection error control unit 3270 turns on the tray full tank error flag in the error flag temporary storage unit 3221. Next, in step 4196-3, the due-payment stop abnormality detection error control means 3270 transmits a tray full command to the sub-control board S side, and proceeds to step 4197-1. On the other hand, in the case of No in step 4196-1, in step 4196-4, the error control means 3270 at the time of detecting a stoppage due to payout turns off the tray full tank error flag in the error flag temporary storage means 3221. Next, in step 4196-5, the payout stop abnormality detection error control means 3270 transmits a pan full cancellation command to the sub-control board S side, and proceeds to step 4197-1.

Next, in step 4197-1, the payout stop abnormality detection error control means 3270 determines whether or not a connection abnormality of the card unit R is detected. In the case of Yes in step 4197-1, in step 4197-2, the error control means 3270 at the time of detecting a stoppage requiring payment turns on the CR unit unconnection error flag in the error flag temporary storage means 3221, and then in step 4198-1. Move to. On the other hand, in the case of No in step 4197-1, in step 4197-3, the error control means 3270 at the time of detection of a stop due payment abnormality turns off the CR unit non-connection error flag in the error flag temporary storage means 3221, and then in step 4198. Move to -1.

Next, at step 4198-1, the payout stop abnormality detection error control means 3270 refers to the error flag temporary storage means 3221 to refer to a part of the error relating to the payout operation stop (for example, an excessive payout error, a prize ball device). Error, payout motor operation error, payout operation incomplete game ball detection, payout motor error, switch non-passage error) It is determined whether or not all flags are off.

If Yes in step 4198-1, in step 4198-2, the payout stop abnormality detection error control unit 3270 refers to the error flag temporary storage unit 3221 to check the communication error flag, the prize ball device error flag, and the tray full. It is determined whether all the error flags of the error flag and the CR unit non-connection error flag are off. If Yes in step 4198-2, in step 4198-3, the payout stop abnormality detection error control means 3270 executes the normal payout operation in the payout control means 3300 (that is, payout operation in step 4198-4 described later). When the process is temporarily stopped, the payout operation is restarted) and the process proceeds to the next process (process of step 4200). On the other hand, in the case of No in step 4198-1 or step 4198-2, in step 4198-4, the payout stop abnormality detection error control means 3270 forcibly suspends the payout operation in the payout control means 3300, and then Process (process of step 4200).

Next, FIG. 53 is a flowchart of the prize ball payout related information receiving process (to the main control board) according to the subroutine of step 4200 of FIG. Here, the first half of the flow is an information reception process from the main control board M (and a process of setting the number of prize balls paid out accordingly), and the second half of the flow is an information transmission process to the main control board M. Therefore, in the first half, the information reception process from the main control board M (and the accompanying process of setting the number of paid prize balls) will be described. First, in step 4205, the main side reception control means 3111 causes the payout state flag temporary storage means. 3311, it is determined whether or not the prize-ball paying-out flag is off. Here, the "prize ball payout flag" means that the prize ball payout process is being executed on the payout control side (when the payout motor of the payout device is in a driving operation, the ball passing waiting time, the motor pause time). It is a flag that is turned on when it is in the middle). If Yes in step 4205, in step 4210, the main-side reception control means 3111 refers to the main-side reception information temporary storage means 3111a and determines whether or not a prize ball payout command has been received. In the case of Yes in step 4210, in step 4215, the payout control means 3300 accesses the flag area of the payout state flag temporary storage means 3311 and turns on the prize ball payout start permission flag. Next, in step 4220, the payout control means 3300 derives the prize ball payout number to be paid out this time based on the prize ball payout command information temporarily stored in the main side reception information temporary storage means 3111a, and pays out the prize ball payout. The number information is set in the payout counter 3312, and the process proceeds to the next process (step 4225). Thus, the process for setting the number of prize balls to be paid out when the normal prize ball payout process is executed is completed. Even if No in Steps 4205 and 4210, the process moves to the next process (Step 4225).

Next, the information transmission process to the main control board M will be described. First, in step 4225, the transmission control unit 3120 refers to the error flag temporary storage unit 3221 to determine whether or not the payout related error transmission flag is ON. To judge. Here, the "payout-related error transmission flag" is used when the above-mentioned payout-related error {payout motor operation error, excessive payout error, ball out error, ball shortage error, payout motor error, payout stop error} occurs. The flag is turned on and turned off after the error notification is given to the main control board M side. If Yes in step 4225, the error control means 3200 turns off the payout related error transmission flag in the error flag temporary storage means 3221 in step 4230. Then, in step 4235, the transmission control means 3120 transmits the payout related error information set in the payout related error information temporary storage means 3121 to the main control board M side, and proceeds to the next process (step 4240). Even if No in step 4225, the process moves to the next process (step 4240).

Next, in step 4240, the transmission control means 3120 refers to the payout state flag temporary storage means 3311 and determines whether or not the prize ball payout completion flag is on. Here, the “prize ball payout completion flag” is a flag that is turned on when the payout control means 3300 determines that the prize ball payout is completed. In the case of Yes in step 4240, in step 4245 the transmission control means 3120 accesses the flag area of the payout state flag temporary storage means 3311 and turns off the prize ball payout completion flag. Then, in step 4250, the transmission control means 3120 transmits information indicating that the prize ball payout has been completed to the main control board M side, and the next process {the prize ball payout control process of step 4300 (start prize ball payout)・Starting motor drive)}. Even if No in step 4240, the process proceeds to the next process {prize ball payout control process in step 4300 (prize ball payout start/motor drive start)}. This is the end of the prize ball payout completion information transmission process.

Next, FIG. 54 is a flowchart of the prize ball payout control process (prize ball payout start/motor drive start) according to the subroutine of step 4300 of FIG. 46. Here, the process is a process at a previous stage of executing the motor drive process of the next step 4400, and the number of motor drive steps and the like are received in response to reception of the prize ball payout command from the main control board M side. This is the process of setting. First, in step 4305, the payout control means 3300 refers to the payout state flag temporary storage means 3311 and determines whether or not the prize-ball payout start permission flag (see step 4215 of FIG. 53) is on. In the case of Yes in step 4305, in steps 4310 and 4315, the payout control means 3300 accesses the payout state flag temporary storage means 3311, turns on the prize ball payout flag and turns off the prize ball payout start permission flag. To do.

Next, in step 4320, the payout control means 3300 determines whether or not the number of prize balls paid out set in the payout counter 3312 is equal to or larger than a predetermined number (for example, 3). In the case of Yes in step 4320, in step 4325, the payout control means 3300 temporarily stores the counter value (n) in the step counter temporary storage means 3313 so as to pay out a predetermined number of pieces, and proceeds to step 432. The counter value (n) temporarily stored here is the number of steps of the stepping motor. On the other hand, in the case of No at step 4320, the payout control means 3300 temporarily stores the counter value (n) in the step counter temporary storage means 3313 so that the prize ball payout number set in the payout counter 3312 is paid out, Moving to 4332.

Next, in step 4332, the payout control means 3300 sets the planned payout number in the current unit payout operation (that is, the payout number planned in step 4325 or step 4330) in the unit payout counter 3317. Next, at step 4335, the payout control means 3300 sets 0 as the exciting stator position specifying counter value (j). Here, the excited stator position identification counter indicates the relative position of the rotor with respect to the stator, and "0" corresponds to the default position during the payout standby (stop). Next, in step 4337, the payout control means 3300 causes the normal operation excitation method related to the stepping motor operation (for example, the well-known 2-2 phase excitation method) and the normal operation one-step switching speed (for example, 3 ms). ) Is set. Next, at step 4338, the payout control means 3300 sets a predetermined value (for example, 500 ms) as the ball passing waiting time/motor pause time related to the stepping motor operation in the ball passing waiting timer 3315. Next, at step 4339, the payout control means 3300 accesses the payout state flag temporary storage means 3311 and turns off the retry operation execution flag. Here, the retry operation in-execution flag is a flag that is turned on during execution of the retry operation related to the stepping motor operation as described above. Then, in step 4340, the payout control means 3300 accesses the payout state flag temporary storage means 3311, turns on the motor driving flag, and performs the next process {step 4400 award ball payout control process (motor drive end/prize. When the ball payout ends)}.

On the other hand, in the case of No in step 4305, in step 4345, the payout control means 3300 refers to the payout state flag temporary storage means 3311 and determines whether or not the motor driving flag is on. In the case of Yes in step 4345, the motor has already been driven, and therefore the process proceeds to the next process {prize ball payout control process of step 4400 (when motor driving ends/prize ball payout end)}.

On the other hand, in the case of No at step 4345, at step 4350, the payout control means 3300 accesses the payout state flag temporary storage means 3311 and determines whether or not the prize ball payout continuation flag is off. Here, the award ball payout continuation flag is a case where the award ball payout operation should be continued after the stepping motor operation for a predetermined number of steps in the unit payout operation and the ball passing waiting time/motor rest time has elapsed ( The detailed condition will be described later). In the case of Yes in step 4350, the process proceeds to the next process {prize ball payout control process in step 4400 (at the time of motor drive end/prize ball payout end)}.

On the other hand, in the case of No in step 4350, in step 4352, the payout control means 3300 accesses the payout state flag temporary storage means 3311 and turns off the prize ball payout continuation flag. Then, in step 4354, the payout control means 3300 refers to the unit payout counter 3317, and determines whether or not the counter value is greater than 0 (that is, whether all of the planned payout numbers in the present unit payout operation have been paid out. Whether or not) is determined. If Yes in step 4354, in step 4356, the payout control unit 3300 accesses the payout state flag temporary storage unit 3311, turns on the ball path abnormality detection flag, and proceeds to step 4320. On the other hand, in the case of No in step 4354, the process proceeds to step 4320 without executing step 4356. That is, when the prize ball payout continuation flag is ON, the process of setting the motor driving step number and the like is executed again without receiving the prize ball payout command from the main control board M as a trigger. When it is determined that not all of the planned number of payouts due to the current unit payout operation have been paid out, an abnormal occurrence that causes a ball out error or a ball shortage error is detected.

Next, FIG. 55 is a flowchart of the prize ball payout control process (at the end of motor driving/at the end of prize ball payout) according to the subroutine of step 4400 of FIG. Here, this process is a termination process when all the scheduled driving ends of the motors have been executed in the previous process (step 4300), or when all the scheduled prize payouts have been executed. .. Here, the motor drive end process is executed in steps 4402 to 4419, the game ball detection process is executed in steps 4420 to 4425, and the prize ball payout end process is executed in steps 4430 to 4462.

First, the motor drive end processing will be described. First, in step 4402, the payout control unit 3300 refers to the flag area of the payout state flag temporary storage unit 3311 to determine whether or not the prize ball payout flag is on. To do. In the case of Yes in step 4402, in step 4405, the payout control unit 3300 refers to the flag area of the payout state flag temporary storage unit 3311 and determines whether or not the motor driving flag is on. In the case of Yes in step 4405, in step 4410, the payout control means 3300 refers to the counter value (n) in the step counter temporary storage means 3313 and determines whether or not the counter value is 0, that is, the step of FIG. 54. It is determined whether all the step numbers in the current unit payout operation set in step 4325 or step 4330 have been executed. In the case of Yes in step 4410, in step 4415, the payout control means 3300 accesses the flag area of the payout state flag temporary storage means 3311 and turns off the motor driving flag. Next, in step 4416, the payout control means 3300 refers to the flag area of the payout state flag temporary storage means 3311 and determines whether or not the retry operation in-execution flag is on. If Yes in step 4416, in step 4417 the payout control means 3300 accesses the flag area of the payout state flag temporary storage means 3311, turns off the retry operation execution flag, and proceeds to step 4418. On the other hand, if No in step 4416, the process moves to step 4418. Next, at step 4418, the payout control means 3300 maintains the resting state of the stepping motor (in this example, the excitation output is lowered and then continuously excited to the current excitation stator position identification counter value (j)). Next, in step 4419, the payout control means 3300 starts the ball passage waiting timer 3315, and proceeds to step 4420. Even if No in step 4405 or step 4410, the process moves to step 4420. This is the end of the motor drive end process.

Next, the game ball detection process will be described. First, in step 4420, the payout control means 3300 determines whether or not a game ball detection signal has been received from the payout count sensor KE10s. If Yes in step 4420, in step 4422, the payout control unit 3300 subtracts 1 from the counter value temporarily stored in the unit payout counter 3317. Next, in step 4425, the payout control means 3300 subtracts 1 from the counter value temporarily stored in the payout counter 3312, and proceeds to step 4430. Even if No in step 4420, the process moves to step 4430. Here, in this example, the value of the payout counter 3312 is configured to be decremented by 1 each time a ball is detected. However, the present invention is not limited to this, and a plurality of game balls are detected. If so, the value corresponding to the number of entered balls may be subtracted. This is the end of the game ball detection process.

Next, the prize ball payout end processing will be described. First, in step 4430, the payout control means 3300 refers to the payout counter 3312 and determines whether or not the count value is 0 or less. In the case of Yes in step 4430, in step 4431, the payout control means 3300 refers to the flag area of the payout state flag temporary storage means 3311 and determines whether or not the motor driving flag is on. In the case of Yes in step 4431 (that is, when the number of game balls corresponding to the payout is detected by the sensor even though the driving of the motor related to the payout is not completed), in step 4432, The payout control means 3300 turns on the payout incomplete game ball detection flag in the error flag temporary storage means 3221, and proceeds to step 4435. On the other hand, if No in step 4431, the process moves to step 4435.

Next, in step 4435 and step 4440, the payout control means 3300 accesses the payout state flag temporary storage means 3311, turns off the prize ball payout flag and turns on the prize ball payout completion flag. Next, in step 4441, the payout control means 3300 refers to the payout counter 3312 and determines whether or not the count value is less than 0. If Yes in step 4441, in step 4442 the payout control means 3300 turns on the payout abnormality detection flag in the payout state flag temporary storage means 3311. Next, in step 4443, the payout control unit 3300 refers to the payout counter 3312, and based on the count value, the number of overpayments (for example, if the counter value is "-3", the number of overpayments is "3"). Is temporarily stored in the payout process related information temporary storage means 3310, and the process proceeds to the next process {prize ball payout control process of step 4500 (during motor drive)}. Even when No in step 4441 (that is, when the count value of the payout counter 3312 is 0 and the predetermined number of payouts is normally paid out), the following process (the prize ball payout control process of step 4500) is performed. (When executing motor drive)}. In this example, the overpayment is detected when the value of the payout counter 3312 becomes 0 or less, but the present invention is not limited to this. For example, after the driving of the motor related to the payout is completed. Detection of excess payout (value of payout counter 3312 is less than 0 when a predetermined time (for example, a detection waiting time sufficient for the gaming balls paid out by the drive to be detected by the payout count sensor KE10s) has elapsed. (Determination of whether or not) is executed (that is, the overpayment is an unexpected situation in which the number of game balls exceeds the number of game balls to be paid out). It means that it occurred, and this unexpected situation that is extremely unlikely to occur by design means that there is a problem in one of the payout mechanisms or that a fraudulent act occurred while performing the payout operation. It means that it was likely done).

On the other hand, in the case of No in step 4430, in step 4445, the payout control means 3300 refers to the timer value of the ball passage waiting timer 3315 and determines whether or not the timer value is 0. If Yes in step 4445, in step 4446, the payout control unit 3300 turns on the switch non-passage error detection flag in the error flag temporary storage unit 3221 (note that in this example, after the payout operation is completed, Even if the ball passing waiting time of time has passed, if the number of game balls related to the payout operation is not detected, it is determined that a switch non-passage error has occurred immediately. There is no limitation, and it may be configured to determine that a switch non-passage error has occurred when the event occurs multiple times).

Next, in step 4447, the payout control means 3300 accesses the payout state flag temporary storage means 3311 and determines whether or not the retry operation execution standby flag is off. Here, the retry operation execution standby flag is a flag that is turned on when a motor error occurs during motor driving as described above. In the case of Yes in step 4447, in step 4450, the payout control means 3300 accesses the payout state flag temporary storage means 3311, turns on the prize ball payout continuation flag, and performs the next process {the prize ball payout control process of step 4500 ( When executing motor drive)}. On the other hand, in the case of No in step 4447, in steps 4460 and 4462, the payout control unit 3300 accesses the payout state flag temporary storage unit 3311, turns off the retry operation execution standby flag, and sets the retry operation execution permission flag. The process is turned on, and the process proceeds to the next process {prize ball payout control process of step 4500 (during motor drive)}. Even if No in step 4445, the process proceeds to the next process {prize ball payout control process in step 4500 (during motor driving)}.

Here, in the case of No in step 4402 (that is, when the prize ball payout process is not being executed), in step 4470, the payout control means 3300 determines whether or not the game ball detection signal is received from the payout count sensor KE10s. To judge. If Yes in step 4470, in step 4472 the payout control unit 3300 turns on the payout motor operation abnormality detection flag in the payout state flag temporary storage unit 3311, and the next process {prize ball payout control process of step 4500 ( When executing motor drive)}. Even if No in step 4470, the process proceeds to the next process {prize ball payout control process in step 4500 (during motor drive)}.

Next, FIG. 56 is a flowchart of the prize-ball payout control process (during motor driving) according to the subroutine of step 4500 of FIG. Here, the process is a process of actually executing the motor drive based on the number of steps set in the previous process (step 4400). First, in step 4505, the payout control means 3300 refers to the flag area of the payout state flag temporary storage means 3311 and determines whether or not the motor driving flag is on. The motor driving flag is a flag that is turned on when a predetermined step counter number is set in the step counter temporary storage means 3313 (see step 4340 in FIG. 54), and corresponds to the predetermined step counter number. It is a flag that turns off when all the excitation is performed. Here, in the case of Yes in step 4505, the payout control unit 3300 subtracts 1 from the step counter value (n) of the step counter temporary storage unit 3313 in step 4510. Next, in step 4520, the payout control means 3300 updates (1 increment) the exciting stator position specifying counter value (j) in the exciting stator position specifying counter value temporary storage means 3314. Next, at step 4525, the payout control means 3300 excites the stator corresponding to the excited stator position identification counter value (j) in the excited stator position identification counter value temporary storage means 3314 based on the predetermined excitation method and switching speed. ..

Next, in step 4530, the payout control means 3300 determines whether or not the counter value (j) in the excitation stator position identification counter value temporary storage means 3314 is the confirmation timing of the rotor position confirmation sensor KE10ms. Here, the confirmation of the rotor position confirmation sensor KE10ms is performed for the purpose of confirming whether or not an abnormal operation (out-of-step phenomenon due to ball glaze or the like) related to the motor operation has occurred. In the case of Yes in step 4530, in step 4550, the payout control means 3300 refers to the presence/absence of a detection signal from the rotor position confirmation sensor KE10ms. Then, in step 4555, the error control means 3200 determines whether or not the rotor is not rotating correctly, that is, whether or not a motor error has occurred, based on the presence or absence of the detection signal in step 4550. If Yes in step 4555, in step 4560 the error control unit 3200 turns on the motor position abnormality flag in the payout state flag temporary storage unit 3311, and proceeds to the next process (motor error process in step 4600). Even if No in step 4530, the process proceeds to the next process (process at the time of motor error in step 4600). If No in step 4555, in step 4565, the error control unit 3200 temporarily stores the error flag. The motor error flag in the means 3221 is turned off, and the process proceeds to the next process (process at the time of motor error in step 4600).

Next, FIG. 57 is a flowchart of the processing at the time of motor error according to the subroutine of step 4600 of FIG. First, the purpose of this processing is to forcibly shift the motor drive to a rest state when a motor error is detected. First, in step 4605, the payout control unit 3300 refers to the payout state flag temporary storage unit 3311 and determines whether the motor position abnormality flag is on. Here, as shown in step 4560 of FIG. 56, it is detected whether or not the motor is at a predetermined rotation position at a predetermined detection timing, and if the motor is not at the predetermined rotation position, step out, etc. The motor position abnormality flag is turned on. In the case of Yes in step 4605, in step 4610, the payout control means 3300 accesses the payout state flag temporary storage means 3311 and turns off the motor position abnormality flag. Next, at step 4615, the payout control means 3300 turns on the payout motor abnormality detection flag in the payout state flag temporary storage means 3311. Then, in step 4620, the error control unit 3200 clears the step counter value (n) in the step counter temporary storage unit 3313, and shifts to the next process (error detection error control process of step 4100). This is because the number of steps set this time is no longer executed due to the occurrence of a motor error, and after the count value is cleared, the motor drive shifts to the idle state (step 4410 and step in FIG. 55). 4415). Even if No in step 4605, the process shifts to the next process (error control process at abnormality detection in step 4100).

Next, with reference to FIGS. 58 to 78, the control processing executed on the sub-main control section SM side will be described. First, FIG. 58 is a main flowchart of the sub control board S side (particularly, the sub main control section SM side) in the pachinko game machine according to the present embodiment. Here, the process of FIG. 11D is a process on the side of the sub-main control unit SM which is executed after resetting when the power of the gaming machine is turned on. That is, when the power of the gaming machine is turned on, in step 5002, the CPUSC of the sub control board S executes an initial process based on the information received from the main side (main control board M side) (for example, RAM clear information). Is received → the sub-side RAM is initialized, and when various information commands are received → performance related information at the time of power interruption is reset in the sub-side RAM). Next, in step 5004, the CPUSC of the sub-control board S deletes the information indicating that the trigger is held (held in the prefetch lottery) from the temporarily stored information related to holding (the trigger is held). If there is no hold having the information of “No” in the hold, the process shifts to the next process without executing this process), and the hold display mode and the variation suggestion display are all displayed in “white” (prefetch effect). Reset the process according to). The process at the time of power failure is not limited to this, and even after the power is restored, the information indicating that the trigger is on hold, the information related to the hold display mode, and the state related to the display mode of the change suggestion display can be deleted. Instead, it may be configured such that various effects such as look-ahead effects can be continued. In such a configuration, for example, a sub area is provided with an evacuation area that can maintain information even during an electric power failure, and when power failure occurs, the information related to the performance is backed up in the evacuation area and the power is restored. It may be configured to restore the information backed up at times. In addition, when the power is restored, when the fluctuation starts, when the fluctuation stops, or when the hold occurs (also regarding the hold other than the newly generated hold), the main control board M side displays the information related to the hold and the content of the change suggestion display. It may be configured to receive again (note that although not particularly shown in this example, only information relating to the number of holdings is transmitted from the main control board M side at the time of restoration from power failure (see the content of holding). Such information is not transmitted). Therefore, the information related to the hold that was present when the power was cut off does not exist after the power is restored, and therefore the prefetch effect cannot be executed for the hold (the main side holds the power when the power is restored. May be configured to be received, and the prefetch effect may be executed for the hold). In addition, when the power failure occurs during the change of the decorative pattern, if there is no function of maintaining the information at the time of the power failure, until the end command of the change from the main control board M side. During the period, a dark screen (for example, a screen displaying "preparing" etc.) will be displayed}. After that, the process proceeds to the loop process of repeatedly executing (f) which is the iterative process routine of the sub-main controller SM. Here, when (f) is executed, the CPUSC of the sub-control board S first executes a customization control process, which will be described later, in step 5200, as shown in the process of FIG. Next, in step 5500, the CPUSC of the sub control board S executes a pending information management process described later. Next, in step 5700, the CPUSC of the sub-control board S executes a decorative symbol display content determination process described later. Next, in step 5800, the CPU SC of the sub-control board S executes a decorative symbol display control process described later. Next, in step 5900, the CPUSC of the sub-control board S executes a special game-related display control process described later. Next, in step 5999, the CPUSC of the sub-control board S executes a display command transmission control process (sends the command set by these series of sub-routines to the sub-sub control unit SS side), and ends this repeating process routine. To do.

As described above, the sub-main control unit SM adopts a mode in which the sub-main side routine (S5200 to S5999) is looped after reset. Further, the process of FIG. 6E is an interrupt process of the sub-main control unit SM, and the signal from the STB signal line in the main control board M described above is one terminal of the CPU of the sub-main control unit SM (in this example, , NMI terminal) is the processing flow (e). That is, when an NMI interrupt occurs in the CPU of the sub-main control unit SM (when the STB signal line is turned on), the sub-main control unit SM causes the command input port (from the main control board M side) in step 5005. Check the input port of the data signal line). Then, in step 5006, the sub-main control unit SM sends the command transmitted from the main control board M side to the RAM (for example, main-side information temporary storage means SM11b) on the sub-main control unit SM side based on the confirmation result. Is temporarily stored, and the processing that was being executed immediately before this interrupt processing is restored.

Next, FIG. 59 is a flowchart of the customization control process according to the subroutine of step 5200 in FIG. First, in step 5202, the CPUSC of the sub-control board S has a non-gaming period measurement timer value equal to or greater than a first guidance value (a timer value at which a first customization guidance screen is displayed, which is 5 seconds in this example). Or not. If Yes in step 5202, in step 5204, the CPUSC of the sub-control board S displays the first customization guide screen on the forefront of the display area SG10. In this example, the player can change the volume level, the light amount level, and the notice frequency (these may be collectively referred to as “game machine customization”), and a screen for executing game machine customization is displayed. The display notifying the transition condition of is referred to as a customization guide screen. Note that the customization guide screen has a two-stage display mode depending on the non-game period, and since the non-game period can be displayed in a short time, the first customization guide screen→the second customization guide screen is displayed. The mode for notifying the transition condition of the screen for executing the game machine customization is not limited to this. (1) Display the first customization guide screen at the timing when the non-gaming period measurement timer value becomes 5 seconds. Without, the sub input button SB and the cross key SB-2 are turned on (the lamps provided on the sub input button SB and the cross key SB-2 are turned on), and the timing when the non-game period measurement timer value becomes 75 seconds Display the second customization guide screen at, (2) Sub-input button at the timing when the non-game period is started (the non-game period measurement timer value = 0 and the measurement of the non-game period measurement timer is started) The SB and the cross key SB-2 may be turned on. Next, in step 5250, the CPUSC of the sub-control board S executes a customization guide screen display control process, which will be described later. Next, in step 5300, the CPUSC of the sub-control board S executes a customization-in-progress display control process, which will be described later, and shifts to the next process. In the case of No in step 5202, in step 5350, the CPU SC of the sub-control board S executes in-game customization control processing, which will be described later, and shifts to the next processing.

Next, FIG. 60 is a flowchart of the customization guide screen display control processing related to the subroutine of step 5250 in FIG. First, in step 5252, the CPU SC of the sub control board S determines whether or not the up and down buttons of the cross key SB-2 have been operated. The cross key SB-2 has four buttons that can be operated: an upper button, a lower button, a right button, and a left button. If Yes in step 5252, in step 5255, the CPUSC of the sub-control board S is displaying the customization guide screen (the first customization guide screen and the second customization guide screen are collectively referred to as the customization guide screen). Or not. If Yes in step 5255, in step 5256, the CPUSC of the sub-control board S erases the displayed customization screen, displays the light amount adjustment screen on the forefront of the display area SG10, and proceeds to step 5268. On the other hand, if No in step 5255, the process moves to step 5268. If the up and down buttons of the cross key SB-2 are operated while the standby demo screen is displayed, the light intensity adjustment screen (the screen for executing the light intensity adjustment) is not displayed, but the light intensity adjustment is possible. (It is the same process as the in-game customization control process described later).

If No in step 5252, in step 5258 the CPU SC of the sub control board S determines whether or not the sub input button SB has been operated. If Yes in step 5258, in step 5260, the CPUSC of the sub-control board S deletes the displayed customization screen and standby demo screen, and displays the customization in progress screen (screen for switching the notice frequency) in the display area. It is displayed on the foreground, and the process moves to step 5268. The structure of the standby demo screen applicable to this example is (1) the volume of the standby demo screen displayed is relatively low or silent (details will be described later), (2) standby The demo display period (the maximum display period of the period in which the standby demo screen can be displayed) is longer than the demo start value (240 seconds) (for example, 660 seconds), and (3) the standby demo screen Even if there is no game ball entering the main game starting port during the display, the display of the standby demo screen ends due to the detection of the firing handle D44. (4) The non-game period starts in the time-saving game state Even if the value (240 seconds) is reached, the standby demo screen is not displayed, and only the volume is the same as when the standby demo screen is displayed. And, when the standby demo screen is being displayed (or a specific period of the non-gaming period), or the maximum volume that can be output is relatively low (may be in a mute state), the firing handle D44 is detected. Display a specific right-handing instruction display or output sound (details will be described later). (6) When the sub-input button SB is operated while the standby demo screen is displayed, the customization execution screen is displayed on the front layer. , The symbol fluctuation stop display screen (the state where the normal decorative pattern stop pattern is displayed) is displayed on the rear layer, and the pattern fluctuation stop display screen is displayed depending on the detection of the firing handle D44, and the cross key SB-2 is pressed. The standby demo screen may continue to be displayed when operated, but the volume and light amount may be changed. Incidentally, as a specific display example of the standby demo screen, a moving image for explaining a game or a motif introduction (character introduction or notice introduction) of a gaming machine may be displayed. The display condition of the standby demo screen is not limited to the fact that the non-gaming period reaches the demo start value (240 seconds in this example), and for example, the time when the operation of the firing handle D44 is not detected. (Or, the time when the game ball is not fired) reaches the predetermined time A (10 seconds), the standby demo screen is displayed, and the maximum display time of the standby demo screen is the predetermined time B (100 seconds). May be. When configured in this way, the predetermined time A (10 seconds) is longer than the shortest fluctuation time (for example, 1.5 seconds) in the gaming machine and is longer than the maximum fluctuation time (for example, 240 seconds). It's a short time. The predetermined time B (10 seconds) is also longer than the shortest fluctuation time (eg, 1.5 seconds) in the gaming machine and shorter than the maximum fluctuation time (eg, 240 seconds). Further, it is the time when the operation of the firing handle D44 is not detected (or the time when the game ball is not fired), compared to the average time from the time when the game ball is fired on the game board surface to the time when it flows into the outlet D36. It is preferable that the predetermined time A (10 seconds) is longer (in order to prevent the standby demo screen from being displayed despite the player firing the game ball).

If NO in step 5258, in step 5262 the CPU SC of the sub-control board S determines whether or not the left/right button of the cross key SB-2 has been operated. If Yes in step 5262, in step 5264 the CPU SC of the sub control board S determines whether or not the volume adjustment prohibition flag is off. If Yes in step 5264, in step 5265 the CPUSC of the sub control board S determines whether or not the customization guide screen is being displayed. In the case of Yes in step 5265, in step 5266 the displayed customization screen is erased, the volume adjustment screen is displayed on the forefront of the display area SG10, and the process proceeds to step 5268. If the left and right buttons of the cross key SB-2 are operated while the standby demo screen is displayed, the volume adjustment screen (the screen for executing the volume adjustment) is not displayed, but the volume adjustment is possible. (It is the same process as the in-game customization control process described later). Also, the volume adjustment screen may be hidden while the symbol variation display, the standby demo screen, or the symbol variation stop display screen is displayed, or the volume adjustment screen is always displayed while the symbol variation stop display screen is displayed. It may be configured so that the volume level can be adjusted and the display of the volume adjustment screen can be changed according to the volume level by using the cross key SB-2. Alternatively, the cross key SB-2 may be displayed so that the volume level can be adjusted and the display of the volume adjustment screen can be changed according to the volume level.

Here, to summarize the processing of steps 5262 to 5266,
(1) When the left and right buttons of the cross key SB-2 are operated when the first customization guide screen is displayed and the volume adjustment prohibition flag is ON, the volume adjustment screen is not displayed, and the volume level Not changeable (2) When the left and right buttons of the cross key SB-2 are operated while the first customization guide screen is displayed and the volume adjustment prohibition flag is OFF → The volume adjustment screen is displayed, and according to the display Volume level can be changed (3) When the standby demo screen is displayed and the volume adjustment prohibition flag is OFF, the left and right buttons of the cross key SB-2 are operated → The volume adjustment screen is not displayed (standby The demo screen remains displayed) and the volume level can be changed.

Next, in step 5268, the CPU SC of the sub-control board S determines whether or not the non-gaming period measurement timer value is equal to or greater than the demonstration start value (240 seconds). If Yes in step 5268, in step 5270, the CPU SC of the sub-control board S displays the standby demo screen on the forefront of the display area SG10. Next, in step 5272, the CPU SC of the sub-control board S sets the demo screen mode to the sub-side game state type, and proceeds to the next process (process of step 5300). In the present embodiment, the standby demo screen is displayed when the non-gaming period measurement timer value reaches the demo start value, but the display start condition of the standby demo screen is not limited to this. No, for example, when the non-game period measurement timer value becomes the demo start value in the non-time reduction game state, the standby demo screen is displayed, while the non-game period measurement timer value starts in the time reduction game state. When the value is reached, the standby demo screen may not be displayed (in the time shortening game state, the standby demo screen is not displayed regardless of the non-game period measurement timer value). In the case of such a configuration, the volume output when the non-game period measurement timer value becomes the demo start value is "1" which is the volume of the demo screen mode or no sound regardless of the game state. May be configured to be lower than the current set value of volume (volume determined by the volume switch and the volume level) or to be silent. It may be configured to be lower than the set value of the light quantity (light quantity determined from the light quantity level) or to be silent. Further, in the time shortening game state, the non-gaming period measurement timer may not be measured itself (the timer value is always 0 and the time is not measured).

Further, in the case of No in step 5268, in step 5274, the CPU SC of the sub-control board S sets the non-gaming period measurement timer value to the second guidance value (the timer value at which the second customization guidance screen is displayed. In this example, , 75 seconds) or more. If Yes in step 5274, in step 5276, the CPUSC of the sub-control board S displays the second customization guide screen on the forefront of the display area SG10, and proceeds to the next process (process of step 5300). Even if No in step 5264 or step 5274, the process proceeds to the next process (process in step 5300). While the standby demo screen is being displayed, the customization guide screen is not displayed, but the sub input button SB and the cross key SB-2 are lit (at the edges of the sub input button SB and the cross key SB-2. (A lamp that can be turned on is provided) (the lamp is turned on even when the customization screen is displayed).

Next, FIG. 61 is an example of a customization guide screen image diagram according to the present embodiment. First, the upper left part is the first customization guide screen, the upper right part is the second customization guide screen, and the lower left part is the standby demo screen. When 5 seconds have passed in the non-gaming state from the stop of the symbol fluctuation, The first customization guide screen is displayed. On the first customization screen, it is displayed that the actual device can be customized (the notice frequency is changed) by pressing the sub-input button SB, and the method of adjusting the volume/light amount is not displayed. The display of the first customization screen is semi-transparent, and even if the display of the first customization guide screen and the decorative pattern are displayed in an overlapping manner, the decorative pattern is visible. Further, by pressing the sub-input button SB while the first customization guide screen is displayed, it is possible to customize the actual machine (change the notice frequency).

Next, after the first customization guide screen is displayed, the second customization guide screen is displayed when 70 seconds have passed in the non-gaming state (75 seconds have passed since the non-gaming period). Is displayed. The second customization guide screen has a display mode in which, in addition to the display mode of the first customization guide screen, a volume adjustment guide image and a light amount adjustment guide image are added to the lower portion of the display area SG10. The first customization guidance screen and the second customization guidance screen are semi-transparent, like the first customization guidance screen.

Next, after the second customization guide screen is displayed, when 165 seconds have passed in the non-playing state (240 seconds have passed since the non-playing period), the standby demo screen is displayed. Is displayed. In the standby demo screen, the displays of the first customization guide screen and the second customization guide screen are erased, and the story display and the like are displayed. Incidentally, the standby demo screen is not translucent, and when the display of the standby demo screen and the decorative design are displayed in an overlapping manner, the decorative design cannot be visually recognized or is difficult to see (display of the decorative design). The display area is smaller than the display of the standby demo screen, the display of the decorative pattern is displayed on the rear layer than the display of the standby demo screen, etc.). When the ON adjustment prohibition flag is ON, the display related to the ON adjustment is not displayed on the second customization guide screen.

Next, FIG. 62 is a flowchart of the customization executing display control process according to the subroutine of step 5300 in FIG. 59. First, in step 5302, the CPUSC of the sub control board S determines whether or not the light amount adjustment screen is being displayed. If Yes in step 5302, in step 5304, the CPU SC of the sub control board S determines whether or not the up/down button of the cross key SB-2 has been operated. If Yes in step 5304, in step 5306, the CPUSC of the sub-control board S changes the selected light amount level based on the operation of the cross key SB-2, and executes lighting in the confirmation lighting pattern. , And proceeds to step 5320. In this embodiment, when adjusting the light amount level,
(1) When the light intensity level is selected with the cross key SB-2, the confirmation light pattern corresponding to the light intensity level being selected is turned on. (2) When the light intensity level is determined by the sub input button SB, A confirmation notification display is displayed in the display area SG10 for notifying which light level has been determined (outputs sound).
It is configured as described above.

If No in step 5302, in step 5308, the CPU SC of the sub-control board S determines whether or not the volume control screen is being displayed. If Yes in step 5308, in step 5310, the CPU SC of the sub-control board S determines whether or not the left/right button of the cross key SB-2 has been operated. If Yes in step 5310, in step 5312, the CPUSC of the sub-control board S changes the selected volume level based on the operation of the cross key SB-2, outputs the confirmation sound, and proceeds to step 5320. Transition. In the present embodiment, when adjusting the volume level,
(1) When a volume level is selected with the cross key SB-2, a confirmation sound corresponding to the selected volume level is output. (2) When the volume level is determined with the sub input button SB, the volume level A confirmation notification display is displayed in the display area SG10 for notifying which is determined (outputs a voice).
It is configured as described above. It should be noted that a configuration may be applied in which the volume control screen described above is constantly displayed (or is always displayed during symbol stop display, symbol variation display, etc.) without outputting the confirmation sound.

Further, in the case of No in step 5308, in step 5314, the CPU SC of the sub-control board S determines whether or not the customization execution screen is being displayed. If Yes in step 5314, in step 5316, the CPU SC of the sub-control board S determines whether or not the up/down/left/right buttons of the cross key SB-2 have been operated. If Yes in step 5316, in step 5318, the CPU SC of the sub-control board S switches the notice to be changed based on the operation of the cross key SB-2, and proceeds to step 5318-1. On the other hand, if No in step 5316, the process moves to step 5318-1. Next, in step 5318-1, the CPUSC of the sub control board S determines whether or not the sub input button SB has been operated. If Yes in step 5318-1, then in step 5318-2, the CPU SC of the sub-control board S determines whether or not the left and right buttons of the cross key SB-2 have been operated. If Yes in step 5318-2, in step 5318-3, the CPU SC of the sub-control board S switches the frequency of the target notice. Next, in step 5318-4, the CPU SC of the sub control board S determines whether or not the sub input button SB is operated. If Yes in step 5318-4, in step 5318-5, the CPU SC of the sub-control board S determines the selected notice frequency, erases the customization screen, and proceeds to step 5318-6. On the other hand, in the case of No at step 5318-1, Step 5318-2, and Step 5318-4, at step 5318-7, the CPUSC of the sub control board S determines whether or not a predetermined time (5 seconds) has elapsed. If Yes in step 5318-7, in step 5318-8, the CPU SC of the sub-control board S erases the customization screen, and proceeds to step 5318-6. On the other hand, in the case of No in step 5314 and step 5318-7, the process proceeds to the next process.

Next, in step 5320, the CPU SC of the sub control board S determines whether or not the sub input button SB has been operated, in other words, whether or not the volume level and the light amount level have been determined. If Yes in step 5320, the process moves to step 5324. On the other hand, in the case of No in step 5320, in step 5322, the CPU SC of the sub-control board S determines whether or not a predetermined time (5 seconds in this example) has elapsed from the start of displaying the customized screen. In the case of Yes in step 5322, in step 5324, the CPU SC of the sub-control board S determines the currently selected volume level and light amount level, and then erases the customization screen. As described above, in the present embodiment, when the sub input button SB is operated, or the predetermined time (5 seconds) elapses without operating the sub input button SB in setting the volume level and the light amount level, in the case of the gaming machine Although it is configured to determine the customization setting, the present invention is not limited to this, (1) operation of the firing handle D44 is detected, (2) pattern variation starts, (3) a predetermined entrance (for example, , The first main game starting port A10) may be configured to determine the gaming machine customization settings when a gaming ball enters. In addition, even if the design variation of the decorative pattern is started while the customization screen is displayed, the customization screen remains displayed (the customization screen is displayed in the front layer rather than the variable display of the decorative pattern), and the gaming machine customization is executed. It may be configured as possible.

Next, in step 5325, the CPU SC of the sub-control board S resets and starts the non-gaming period measurement timer (increment timer), and proceeds to the next process (process of step 5500).

As described above, in the present embodiment, the display mode relating to the gaming machine customization from the start of the non-gaming period (the timing when the measurement of the non-gaming period measuring timer starts) is “non-gaming period measuring timer value=0 seconds→ "Start of non-gaming period" → "Non-gaming period measurement timer value = 5 seconds → Start display of first customization guide screen, customization screen (customization in progress screen, light intensity adjustment screen and volume adjustment screen are collectively referred to as customization screen Start time) → "Non-gaming period measurement timer value = 75 seconds → Display start of second customization guide screen" → "Non-gaming period measurement timer value = 240 seconds → Start display of standby demo screen, customization screen End of transitionable period” → “non-game period measurement timer value=900 seconds → execute default setting, start display of power saving screen”, but is not limited to this. For example, “non-game period Measurement timer value = 0 seconds → Start of non-game period "→ "Non-game period measurement timer value = 5 seconds → Start of transition period of customized screen (screen display does not change)" → "Non-game period measurement timer value = 75" Second → Start display of the second customization guide screen, start lighting the lamps provided on the sub-input button SB and the cross key SB-2 "→ "Non-gaming period measurement timer value = 240 seconds → Start display of the standby demo screen and customize" It may be configured such that “the transitionable period of the screen ends”→“non-gaming period measurement timer value=900 seconds→default setting is executed, display of screen during power saving starts”. The start of the shiftable period of the customized screen means that the period in which the customized screen is displayed is started by operating the sub input button SB or the cross key SB-2.

Next, FIG. 63 is an example of an image diagram of a customization guide screen according to the present embodiment. First, in the left part of the figure, when the first customization guidance screen or the second customization guidance screen is displayed on the effect display device SG, the player operates the left and right buttons of the cross key SB-2. The display mode of the volume adjustment setting screen displayed in this case is shown. Specifically, when the first customization guide screen or the second customization guide screen is displayed, when the player operates the left and right buttons of the cross key SB-2, the volume control screen is displayed, and the volume control screen is displayed. When the left button of the cross key SB-2 is pressed during the display of, the confirmation sound from the speaker D24 becomes smaller, and the lighting part (white part) of the volume display of the upper speaker schematic diagram decreases. When the right button of the SB-2 of the cross key is pressed (indicating that the volume level is reduced), the confirmation sound from the speaker D24 becomes louder and the volume display of the upper speaker schematic diagram is displayed. The illuminated portion (white portion) of is increased (indicating that the volume level is increased), and the sub-input button SB is pressed to determine the selected volume level.

Next, the middle part of the figure is displayed when the up/down button of the cross key SB-2 is operated when the first customization guide screen or the second customization guide screen is displayed on the effect display device SG. The display mode of the setting screen of the light amount adjustment is shown. Specifically, when the player operates the up and down buttons of the cross key SB-2, the light intensity adjustment screen is displayed, and the first customization guide screen or the second customization guide screen is displayed while the light intensity adjustment screen is displayed. If the upper button of the cross key SB-2 is pressed, the petal-shaped lighting portion displayed on the effect display device SG is displayed in three levels of "0 → 6 → 12". When the lower button of the SB-2 of the cross key is pushed down (indicating that the light amount level is increased), the petal-shaped lighting portion displayed on the effect display device SG is 12 The light intensity level is reduced in three stages of 1 → 6 → 0 (indicating that the light intensity level decreases), and the light intensity level being selected is determined by pressing the sub input button SB. There is. It should be noted that even if the cross key SB-2 is operated while the standby demo screen is displayed, the volume control screen and the light intensity control screen are not displayed, but the volume level and the light intensity level themselves can be changed. In the figure, the display corresponding to the light amount level is a petal-like display, and the lighting portion is configured to increase in three stages of "0 → 6 → 12", but this is not a limitation. Instead, the lighting portion may be configured to increase in three steps of “1 piece→2 pieces→3 pieces”, or three petal-shaped displays may be provided (display areas having different sizes, The petals may be configured to increase in three stages of “small, medium, and small petals (3), and small to medium to large”.

Next, the right part of the figure is displayed when the sub input button SB is operated while the first customization guide screen, the second customization guide screen or the standby demo screen is displayed on the effect display device SG. The display mode of the customization execution screen is shown. Specifically, when the player operates the sub input button SB, a customization screen (notice customization screen) is displayed, and when the up, down, left, and right buttons of the cross key SB-2 are pressed on the customization screen, the cursor moves, and the sub input button By pressing SB, the notice in which the cursor is positioned is selected (transition to a screen for changing the occurrence frequency of the notice in which the cursor is positioned).

Next, FIG. 64 is a transition diagram showing in detail the flow of customization on the right side of FIG. First, the number of reservations is 0 and the fluctuation is stopped. Next, since the predetermined time has passed, the first customization guide screen is displayed.

Next, since the sub input button SB is operated while the first customization guide screen is displayed, the customization screen (advance customization screen) is displayed. When the cursor is moved by operating the up/down/left/right buttons of the cross key SB-2 and the sub input button SB is operated, it is possible to change the occurrence frequency of the advance notice in which the cursor is located. Here, fox advance notice (fox advance notice and fox advance notice for each color will be described later) is selected.

Next, a screen where you can set the occurrence frequency of the fox notice is displayed, and you can select 1 (occurrence frequency: low) to 5 (occurrence frequency: high) by operating the left and right buttons of the cross key SB-2. (The cursor is designed to move), and the setting is completed by operating the sub-input button SB (the fox notice occurrence frequency is determined to the occurrence frequency at which the cursor is located). ing. The frequency of occurrence is configured to change by about 20% per step.

Next, when the setting is completed, the screen returns to the screen in which the fluctuation is stopped, and the characters "fox reminder custom" is displayed on the effect display device SG. It should be noted that the first customization guide screen may be displayed when a predetermined time has elapsed without proceeding with the game from the completion of the setting.

Next, the fluctuation has started, but at this time also, the characters “fox reminder custom” is displayed on the effect display device SG.

Next, the variation has evolved into super reach, and when it has evolved into super reach, the characters "fox reminder custom" are erased.

(Supplementary notice customization)
The display priority of displaying the customization status currently set (in this case, the character "fox reminder custom") on the effect display device SG is low. Specifically, the display priority is the second decorative design (sub decorative design)> the first reserved sub display> the first decorative design (main decorative design)> the first reserved display> the change suggestion display>notice> custom status Is displayed.

Although it is preferable that the notice is not displayed in duplicate at the display position of the custom status, the notice may be displayed in duplicate. Further, it is preferable to configure so as not to be displayed redundantly with the first decorative symbol, but it may be configured to be displayed redundantly. As the configuration to be displayed redundantly, for example, it may overlap with the display of the custom status during the variable display of the first decorative design, but overlap with the display of the custom status during the stop display of the first decorative design. It may be configured not to.

In the notice customization, only the frequency of occurrence of the notice and the display pattern (for example, in the case of customization in which the display pattern can be selected from A pattern, B pattern, and C pattern) of the customized notice are changed, and the display not related to the customized notice is displayed. Will not be changed. For example, when the frequency of occurrence of the prefetching effect is changed, the background image and the character image are not changed.

The notice customization can be individually customized for a plurality of notices. For example, the look-ahead effect, the next notice, and the white fox notice can be customized.

The customization in the normal state (non-stochastic variation game state) is preferably configured so as not to be affected in the probability variation game state. For example, even if the "normal notice" is customized in the normal state, it is not applied in the probability variation game state. Therefore, the notice customization may be configured to be customizable about the notice in the normal state and the probability variation game state at all times, or the notice in the normal state can be customized in the normal state, and can be customized in the probability change game state. It may be possible to customize the notice in the probability variation game state. Also, if you customize the notice in the normal state, and then become the probability variation game state (when the game state changes) or customize the notice in the probability variation game state, then in the normal state In this case, the setting of the notice customization may be canceled (reset to the default).

(Example of changing notice customization)
The advance notice customization is configured to continue setting until the power is cut off, but the present invention is not limited to this, and the advance notice customization duration is until a predetermined time (for example, 60 minutes) elapses, until the start of the standby demo screen, until the game starts. It may be up to the change of the state (when the continuation period elapses, the setting of advance notice customization is canceled). In addition, after a certain period of time (for example, 30 seconds) in the fluctuation stopped state, "Do you want to cancel the current customization settings?", "Yes" and "No" are displayed on the effect display device SG, and the sub input buttons SB and The advance notice customization may be canceled when “Yes” is selected by operating the cross key SB-2.

In addition to the look-ahead effects, normal notices (step-up notices, notices that usually occur before reach, such as notices for lines, etc.) shown in this figure, the custom target of notice customization is the three major effects (main 3) of the high-expectation effect which is

Also, custom notifications that may occur at specific times (for example, during super-reach) may be collectively enabled (for example, displayed as “super-reach-in-progress”), and notifications that may occur multiple times May be collectively enabled (for example, “preliminary notice of multiple occurrences” or the like is displayed).

It should be noted that a specific notice (for example, a notice for confirming a big hit such as a premiere notice) may be excluded from the custom target. In addition, it is possible to customize the premiere notice, and if there is customization that increases the frequency of occurrence of the premiere notice, not only the pattern that increases the frequency of occurrence of all the premier notices, but some of the premier notices with extremely low probability of occurrence With respect to, it is possible not to change the occurrence frequency. In other words, even if the effect that occurs in 1/100,000 is doubled in 1/50,000, the player cannot experience the premier notice, so it is difficult for the player to experience the part. It is preferable to exclude the premiere notice with a very low occurrence probability from the custom target.

In the gaming machine having the setting (setting value), it is preferable that the ratio of the occurrence frequency to be changed is the same or almost the same when the customization is executed for a certain notice with different setting values. .. For example, in the case of customizing a red fox, which is a notice with a different occurrence probability (occurrence frequency) for each set value, the occurrence frequency of the red fox is less likely to occur in setting 1 (low setting) and higher in setting 3 (higher). If the occurrence frequency is designed with the occurrence frequency of 5 as the reference, and if the occurrence frequency is designed to change from "occurrence frequency: 5" to "occurrence frequency: 4", In the case of 1, the occurrence frequency of "occurrence frequency: 5" in the setting 1 is reduced by 20%, and in the case of setting 3, the occurrence frequency of "occurrence frequency: 5" in the setting 3 is reduced by 20%. As described above, it is preferable that the one-step change rate (20%) of the occurrence frequency is common regardless of the set value. With such a configuration, it is possible to prevent the situation where the player estimates the set value by setting the advance notice customization.

Further, as shown in FIG. 65, the denominator of the probability of occurrence of red fox in the settings 1 to 3 for each stage of occurrence frequency may be different by a fixed number. Specifically, the probability of occurrence of red fox at an occurrence frequency of 1 differs from setting 1/1/500, setting 2:1/490, setting 3:1/480 by 10 in denominator size. The probability of occurrence of red fox at the frequency of occurrence 2 is set to 1:1/400, set 2:1/390, set 3:1/380, and the denominator size differs by 10 each. The probability of occurrence of red fox at occurrence frequency 3 is set to 1:1/300, set 2:1/290, set 3:1/280, and the denominator size differs by 10 each. The probability of occurrence of the red fox at the occurrence frequency 4 differs by 10 in the denominator size by setting 1: 1/200, setting 2: 1/190, setting 3: 1/180. The probability of occurrence of red fox at the occurrence frequency 5 is set 1/100, setting 2:1/90, setting 3:1/80, and the size of the denominator differs by 10 each.

As described above, the denominator size differs by 10 between setting 1 and setting 2 and the denominator size differs by 10 between setting 2 and setting 3 at any occurrence frequency stage.

However, in the occurrence frequency 1, when the probability of occurrence of red fox in setting 1 is used as a reference, the difference between the probability of occurrence of red fox in settings 2 and 3 is 4% at maximum, and it is difficult to experience the setting difference. However, in the frequency of occurrence 5, the difference between the probability of occurrence of red foxes in settings 2 and 3 is 20% at maximum, based on the probability of occurrence of red foxes in setting 1, which makes it easy to experience the difference in settings. Is becoming Therefore, the player needs to infer the set value from the probability of occurrence of red fox for each stage of the occurrence frequency, but setting the occurrence frequency to 5 is advantageous in estimating the set value.

Since the player wants the notification to occur with a probability based on the customized occurrence frequency, the occurrence probability at a low occurrence frequency at a high setting value (for example, the occurrence frequency 1 at setting 3) and the high occurrence frequency at a low setting value are high. It is preferable that the occurrence probability at (for example, the occurrence frequency 2 of the setting 1) is different within a sensible range, and the occurrence probability at a low occurrence frequency at a high setting value (for example, the occurrence frequency 1 of the setting 3). It is not desirable that the occurrence probability at a high occurrence frequency (for example, the occurrence frequency 2 of the setting 1) at a low setting value is close or the same.

In addition, when it is difficult to estimate the set value, the occurrence probability at a low occurrence frequency at a high setting value (for example, the occurrence frequency 1 at the setting 3) and the high occurrence frequency at a low setting value (for example, the occurrence frequency at the setting 1). It is effective to make the occurrence probabilities in 2) close or the same.

The present embodiment has a configuration that allows advance notice customization even during fluctuations, and this configuration will be described using FIG. 66.

First, the fox notice is currently changing, and the fox notice is customized, and the occurrence frequency of the fox notice is set to "5".

Next, the left button of the cross key SB-2 is operated to change the occurrence frequency of the fox notice to "4".

Next, when 5 seconds have passed from the start of fluctuation, the customizable period ends, and the character display of "fox notice 4" is erased.

In this variation, the customization state set at the start of the variation is maintained, and the customization changed during the variation becomes effective from the next variation.

Further, in changing customization, not only changing the frequency of occurrence of the notice for which customization is already set, but also changing the occurrence frequency during change is possible if the notice is customizable.

Specifically, the customizable notice is changed by operating the up and down buttons of the cross key SB-2, and the frequency of occurrence is changed by operating the left and right buttons of the cross key SB-2.

With such a configuration, it is possible to customize the frequency of occurrence of the advance notice at the timing desired by the player without interrupting the game and waiting for the fluctuation stop state.

Next, FIG. 67 is a flowchart of the in-game customization control processing according to the subroutine of step 5350 in FIG. 59. First, in step 5364, the CPU SC of the sub control board S determines whether or not the operation of the up/down button of the cross key SB-2 is detected. If Yes in step 5364, in step 5366, the CPU SC of the sub-control board S changes the notice of customization based on the operation of the cross key SB-2, and shifts to the next process. On the other hand, in the case of No in step 5364, in step 5368, the CPU SC of the sub-control board S determines whether or not the operation of the left and right buttons of the cross key SB-2 is detected. If Yes in step 5368, in step 5370, the CPU SC of the sub-control board S adjusts the occurrence frequency based on the operation of the cross key SB-2, and proceeds to the next process. As described above, in the present embodiment, the advance notice can be customized by operating the cross key SB-2 even when it is not in the non-gaming period (during change). Specifically, the cross key SB-2 is used. The up and down buttons change the notice, the right button of the cross key SB-2 increases the occurrence frequency by one level, and the left button of the cross key SB-2 decreases the occurrence frequency by one level.

In addition, during-game customization (customization during fluctuation) is possible only in the normal state, and may be configured to be impossible in the probability fluctuation game state, or may not be possible during execution of a big hit or a small hit. Good.

It should be noted that, as in the case of customizing the probability of occurrence of the red fox described above, making it possible to change the probability of occurrence of a notice (occurrence frequency), which has a different probability of occurrence for each set value, makes it more convenient for the player by changing the frequency of occurrence. Although it is easy to guess the setting, there is a concern that the degree of advantage between the players may change depending on the presence or absence of knowledge. Therefore, regarding a notice having a different occurrence probability (occurrence frequency) for each set value, the occurrence frequency may not be changed (not included in the change target) by customizing the occurrence frequency of the notice.

Next, FIG. 68 is a flowchart of the pending information management process related to the subroutine of step 5500 in FIG. First, in step 5502, the CPUSC of the sub-control board S, whether or not a command relating to a new hold occurrence (hold information related to the first main game symbol or the second main game symbol) is received from the main control substrate M side. To judge. In the case of Yes in step 5502, in step 5504, the CPUSC of the sub-control board S sets the drawing suspension counter (in the present example, a maximum of four for the first main game and a maximum of four for the second main game). 1” is added. Next, in step 5506, the CPUSC of the sub-control board S sends a command related to the new hold success/failure result and stop symbol information transmitted from the main control board M side to the drawing reservation information temporary storage area (sub-control board S). Area for temporarily storing the information related to the holding by the side). Next, in step 5508, the CPUSC of the sub control board S stores the hold information (particularly, the variation mode group) in the temporary drawing storage area based on the hold generation command transmitted from the main control board M. Store temporarily. In addition, when the information relating to the hit result, the stop symbol, and the variation mode group is not transmitted from the main control board M side, the information is not temporarily stored in the reserved information temporary storage area in step 5506 or step 5508. It will be. Next, in step 5509, the CPUSC of the sub control board S determines whether or not the new suspension is the suspension of the first main game side. If Yes in step 5509, in step 5550, the CPU SC of the sub control board S executes a first main game prefetching determination process, which will be described later, and proceeds to step 5510. Next, in step 5510, the CPUSC of the sub-control board S determines whether or not information indicating that the trigger is on hold is added to the new hold (added in the process of step 5570). It is determined whether the new hold is a trigger hold. In the present embodiment, information indicating that the trigger is held is added to the holding held in the prefetch lottery. If Yes in step 5510, in step 5650, the CPU SC of the sub-control board S executes a prefetch pending content determination process, which will be described later, and proceeds to step 5520. Incidentally, in the case of No in step 5509 (when the new hold is the second main game side hold) or in the case of No in step 5510, the process proceeds to step 5520. In addition, in the case of No in step 5509, in step 5509-1, the CPU SC of the sub control board S executes the second main game pre-reading process (pre-reading determination process, pre-reading process) for executing the pre-reading effect by the fluctuation of the second main game side. The contents determination process, etc.) is performed and the process proceeds to the next process.

On the other hand, in the case of No in step 5502, in step 5511, the CPU SC of the sub control board S determines whether or not the symbol variation display start instruction command has been received from the main control board M side. If Yes in step 5511, in step 5512, the CPUSC of the sub control board S subtracts “1” from the drawing suspension counter. Next, in step 5514, the CPUSC of the sub-control board S temporarily stores the holding information related to the symbol variation (particularly, winning/losing result, stop symbol information, variation mode group, and variation mode random number delimiter information). The remaining pending information is shifted while being deleted from the area. Next, in step 5515, the CPUSC of the sub-control board S displays the variation suggestion display on the variation suggestion display section SG14 in the same display mode as the display manner immediately before the digestion of the digested hold (the digestion concerned). The displayed display mode of the reserved is shifted and displayed as the fluctuation suggestion display). The change suggestion display may be referred to as the change suggestion image. In addition, the display mode immediately before the digestion of the digested hold is blue, then the reserve is digested, and when the variation suggestion display regarding the digested reserve is displayed, the display form of the variation suggestion display is red. It may be configured such that the display mode of the reservation just before the digestion and the display mode of the variation suggestion display after the digestion of the reserve may be different. In such a case, it is preferable that the display mode of the change suggestion display after the hold is exhausted is a display mode with a higher jackpot expectation than the display mode of the hold immediately before the consumption is completed. .. In addition, the display mode of the hold and the change suggestion display is “white→blue→red→rainbow” from the one with a low jackpot expectation. Next, in step 5516, the CPUSC of the sub control board S turns on the symbol content determination permission flag, and proceeds to step 5520. Even if No in step 5511, the process proceeds to step 2520.

Next, in step 5520, the CPUSC of the sub-control board S, on the effect display device SG (especially, the first hold display unit SG12, the second hold display unit SG13), the same number of hold display image as the drawing hold counter value. Is displayed in the determined hold display mode (when the hold display mode does not change, the hold display mode is white), and the process proceeds to the next process (process of step 5700).

Next, FIG. 69 is a flowchart of the first main game prefetching determination processing according to the subroutine of step 5550 in FIG. 68. As will be described later, the processes of steps 5554 to 5558 are processes related to the prohibition condition of the prefetch lottery, and the processes of steps 5560 to 5570 are processes related to the prefetch lottery.

First, in step 5554, the CPU SC of the sub-control board S determines whether or not the current game state is the non-probability variation game state and the non-time shortening game state (low probability/low base). If Yes in step 5554, in step 5556, the CPUSC of the sub-control board S determines whether or not there is a trigger hold in the hold. If Yes in step 5556, in step 5558, the CPU SC of the sub-control board S determines whether or not there is a big jackpot in the hold before the new hold. If Yes in step 5558, in step 5560 the CPU SC of the sub-control board S determines whether or not the new hold is a big hit hold. If Yes in step 5560, it is determined in step 5560-1 whether or not the new suspension is a variation pattern (group 4) for increasing the stage level. If Yes in step 5560-1, in step 5562, the CPUSC of the sub-control board S raises the level of the stage to be won with a predetermined probability (for example, 1/3) and determines whether or not there is a big hit in the pending state. A pre-reading lottery including a stage level-up (which will be described later) that suggests whether or not is executed, and the process proceeds to step 5568. On the other hand, in the case of No in step 5560-1, in step 5562-1, the CPUSC of the sub-control board S executes the prefetch lottery that does not include the stage level up to win with a predetermined probability (for example, 1/3), and The processing moves to 5568. In addition, in the case of No in step 5560 (that is, hold with a loss), in step 5564, the CPUSC of the sub-control board S determines whether or not the new hold is a variation pattern (group 5) for increasing the stage level. Determine whether. If Yes in step 5564, in step 5566, the CPUSC of the sub-control board S executes a pre-reading lottery including a stage level up to win with a predetermined probability (for example, 1/10), and proceeds to the process of step 5568. On the other hand, in the case of No in step 5564, in step 5566-1, the CPUSC of the sub-control board S executes the prefetch lottery that does not include the stage level up to win with a predetermined probability (for example, 1/10), and in step 5568. Move to processing.

On the other hand, in the case of No in step 5554, in step 5554-2, the CPU SC of the sub-control board S determines whether or not the current game state is the probability variation game state and the time reduction game state (high probability/high base state). To judge. If Yes in step 5554-2, in step 5556-2, the CPUSC of the sub control board S determines whether or not there is a trigger hold in the hold. If Yes in step 5556-2, in step 5558-2, the CPU SC of the sub-control board S determines whether or not there is a big hit in the hold before the new hold. If Yes in step 5558-2, in step 5560-2, the CPU SC of the sub control board S determines whether or not the new hold is a big hit hold. In step 5572, the CPUSC of the sub-control board S executes the prefetch lottery to win with a predetermined probability (for example, 1/3), and proceeds to the processing of step 5568.

Next, in step 5568, the CPUSC of the sub-control board S determines whether or not the prefetch lottery executed in the processing of step 5562, step 5562-1, step 5566, step 5566-1, and step 5572 is won. If Yes in step 5568, in step 5570, the CPUSC of the sub-control board S adds information indicating “trigger hold” to the new hold selected in the prefetch lottery, and performs the next process (step 5510). Process). In addition, also in the case of No in step 5556, step 5558, step 5568, step 5555-2, step 5556-2, step 5558-2, and step 5560-2, the process proceeds to the next process (process in step 5510).

Next, FIG. 70 is a configuration diagram of the prefetch lottery table in the prefetch lottery of FIG. 69. In the pre-reading lottery table including the stage level up during the non-probability variation game state and the non-time shortening game, any one of the IDs 0 to 2 is determined according to the lottery value appropriately distributed. Next, in the pre-reading lottery table without stage level up during the non-probability variation game state and during the non-time shortening game, any one of IDs 0 to 3 is determined in accordance with the lottery value appropriately distributed. In the pre-reading lottery table without the stage level up, the stage level up cannot be executed, and it is determined whether or not other pre-reading effects (here, the pending change and the chance line) are executed. The pre-reading lottery table shown in this example shows the number of types of pre-reading effects in a limited manner for the sake of simplification of description, but in reality, various types of lottery are selected based on combinations with other effects. The pre-reading effect to be executed is determined from the result (ID).

In the pre-reading lottery table in the probability variation game state and during the time-reducing game, in order to determine whether or not a predetermined pre-reading effect can be executed, ID0: No pre-reading effect, ID1: Pre-reading effect exists Is done.

Next, FIG. 71 is a flowchart of the prefetch pending content determination processing according to the subroutine of step 5650 in FIG. First, in step 5654, the CPU SC of the sub-control board S determines whether or not it is a look-ahead effect in the non-probability variation game state and the non-time shortening game state. If Yes in step 5654, in step 5656, the CPUSC of the sub-control board S determines whether or not a pending change has been won. If Yes in step 5656, in step 5658, the CPUSC of the sub-control board S refers to the hold change scenario determination table based on the hit result, and based on the trigger hold occurrence hold count, holds in multiple changes until trigger hold. Determine pending change scenarios for changing. On the other hand, if No in step 5656, the process moves to step 5660.

Next, in step 5660, the CPUSC of the sub-control board S determines whether or not the player has won the chance chance (details of lottery and effect for the chance chance will be described later). If Yes in step 5660, in step 5662, the CPUSC of the sub-control board S refers to the chance eye scenario determination table based on the result of the hit or miss, and the chance eye scenario for displaying the chance eye in a plurality of changes until the trigger is held. To decide. On the other hand, if No in step 5660, the process moves to step 5664.

Next, in step 5664, the CPUSC of the sub-control board S determines whether or not the player has won the stage level-up (details of lottery and effect for the stage level-up will be described later). If Yes in step 5660, in step 5662, the CPUSC of the sub-control board S refers to the stage level-up determination table based on the result of the hit or miss, and raises the stage level for increasing the stage level in a plurality of changes until the trigger is held. Determine the scenario and move to the next process. On the other hand, if No in step 5664, the process moves to the next process.

On the other hand, if No in step 5654 (=probability variation game state and time reduction game state), in step 5668, the CPUSC of the sub-control board S determines the effect contents according to the variation mode (variation mode group), and then Process shifts to. The details of the effect contents (prefetch effect in the probability variation game state and the time reduction game state) will be described later.

Next, FIG. 72 is an example of the pending change scenario determination table. In the figure, the pending change scenario determination table (at the time of big hit) that is referred to when the trigger hold is a big hit hold, and the pending change scenario determination table (when the trigger hold is a missed hold) ( (At the time of loss) and. The item "at the time of occurrence" is the hold display mode at the time of trigger hold occurrence, and the item "before 3 changes" is the hold display mode at the end of the pattern change 3 before the pattern change related to trigger hold, " The item "2 before change" is the hold display mode at the end of the symbol change before the change 2 of the symbol change related to the trigger hold, and the item "1 before change" is the symbol before the change 1 of the pattern change related to the trigger hold It is a hold display mode at the end of fluctuation. For example, if "3 before change" is "blue" and "2 before change" is "blue", the change is a hold change as a hold change during the symbol change 2 before the change of the symbol change related to trigger hold. When the production that fails in (change of display mode of hold) is executed and “3 before change” is “blue” and “2 before change” is “red”, 2 of the symbol change related to trigger hold is executed. It is configured such that an effect that succeeds in the hold change (change in the display mode of the hold) is executed during the symbol change before the change. In addition, the pending change scenario is randomly selected by random number, and the pending change is executed in the middle of the symbol variation (it may be configured to perform the pending change at the start of the symbol variation). In addition, as the display mode of the trigger hold, it is "blue → red → rainbow color" from the one with a low jackpot expectation, and when the display mode of the trigger hold changes, the display mode of the trigger hold is the big hit expectation. The display mode is changed to a highly frequent display mode. Also, since "rainbow color" is not selected as the display mode when the trigger hold is lost, when the trigger hold display mode is "rainbow", the trigger hold is a big hit. To be the target. Here, when the hold change is executed in the situation where the trigger hold display mode is "red", the trigger hold display mode is iridescent, so the trigger hold display mode is "red" When the hold change fueling effect is executed in, the player has an expectation that the hold fueling effect is successful. In addition, in the present example, the pending display modes are four types of “white”, “blue”, “red”, and “rainbow”, but the present invention is not limited to this, and the number of types may be increased. However, the changing element may indicate that the hold is changed not by color but by shape or lighting/flashing. Further, as a display mode that suggests a future change in holding, for example, holding of the shape of the treasure box may be displayed, and then the treasure box may be opened and the holding display mode after the change may be changed.

Next, FIG. 73 is a flowchart of the decorative symbol display content determination processing related to the subroutine of step 5700 in FIG. First, in step 5702, the CPU SC of the sub control board S determines whether or not the symbol content determination permission flag is on. If Yes in step 5702, in step 5704, the CPU SC of the sub control board S turns off the symbol content determination permission flag. Next, in step 5706, the CPUSC of the sub-control board S, based on the temporarily stored symbol information (stop symbol/variation mode relating to the main game symbol), the stop symbol of the decorative symbol {for example, the stop relating to the main game symbol) If the design is a jackpot design, it is a flat pattern such as "7,7,7", and if it is a lost design, it is a random pattern such as "1.3.5"} and the variation mode is determined and sub-control is performed. It is temporarily stored in the RAM area of the substrate S.

Next, in step 5300, the CPU SC of the sub-control board S executes an effect content determination process described later. Next, in step 5714, the CPUSC of the sub-control board S turns on the symbol content determination flag, and proceeds to the next process (process of step 5800).

Next, FIG. 74 is a flowchart of the effect content determination processing related to the subroutine of step 5300 of FIG. 73. First, in step 5308, the CPUSC of the sub-control board S determines whether or not there is a trigger hold in the hold. In the case of Yes in step 5308, in step 5310, the CPUSC of the sub-control board S determines the effect contents related to the symbol variation based on the stop symbol and the variation mode of the decorative symbol, and the next process (the process of step 5714). Move to.

On the other hand, in the case of No in step 5308, in step 5312, the CPU SC of the sub-control board S determines whether or not to perform a stirrup effect. If Yes in step 5312, in step 5314, the CPU SC of the sub-control board S determines the effect content related to the symbol variation to be the pending change-inspiring effect, and also refers to the pending change-inspiring effect determination table to determine. Based on the pending change agitation scenario, the effect mode of the pending change agitation effect related to the variation is determined, and the process proceeds to the next process (the process of step 5714). In addition, in the case of No in step 5312, in step 5316, the CPU SC of the sub-control board S, based on the execution timing of the pending change success effect that has been determined, the stop symbol of the decorative symbol, and the variation mode, the effect related to the symbol variation. The contents are determined, and the process proceeds to the next process (process of step 5714).

Next, FIG. 75 is a flowchart of a decorative symbol display control process related to the subroutine of step 5800 in FIG. First, in step 5802, the CPU SC of the sub control board S determines whether or not the symbol content determination flag is on. If Yes in step 5802, in step 5804, the CPU SC of the sub-control board S turns off the symbol content determination flag. Next, in step 5806, the CPU SC of the sub-control board S turns on the symbol variation flag. Next, in step 5809, the CPUSC of the sub-control board S starts the drawing variation time management timer, and proceeds to step 5810. Even if No in step 5802, the process proceeds to step 5810.

Next, in step 5810, the CPUSC of the sub control board S determines whether or not the symbol changing flag is on. If Yes in step 5810, in step 5811, the CPUSC of the sub control board S confirms the timer value of the drawing variation time management timer. Next, in step 5812, the CPUSC of the sub-control board S determines whether or not the variation start timing of the decorative pattern has been reached. If Yes in step 5812, in step 5814 the CPUSC of the sub-control board S sets a variable display command of the decorative pattern (transmitted to the sub-sub-control section SS side in the display command transmission control process of step 5999). , And proceeds to step 5823.

On the other hand, if No in step 5812, in step 5816 the CPU SC of the sub-control board S determines whether or not the temporary stop display timing (temporary stop display timing) of the decorative pattern has been reached. If Yes in step 5816, in step 5818, the CPUSC of the sub control board S sets a stop display command (temporary stop display command) of the decorative pattern (in the display command transmission control process of step 5999, the sub sub control unit SS side). Is transmitted) to the step 5823.

Further, in the case of No in step 5816, in step 5820, the CPUSC of the sub-control board S has reached the display timing of the notice image or reach image based on the variation mode temporarily stored in the RAM area of the sub-control board S. Determine whether or not. If Yes in step 5820, in step 5822 the CPUSC of the sub-control board S sets an image display command related to the notice image or reach image (in the display command transmission control process of step 5999, the sub-sub control unit SS side is set). (Transmitted), and the process proceeds to step 5823. Even if No in step 5820, the process proceeds to step 5823. Next, in step 5823, the CPUSC of the sub control substrate S determines whether or not the stage level-up timing has been reached. If Yes in step 5823, in step 5824, the CPUSC of the sub-control board S executes the level up of the stage, and proceeds to step 5830.

On the other hand, if No in step 5823, in step 5825 the CPU SC of the sub control board S determines whether or not the execution start timing of the pending change has been reached. Here, in this processing, it is determined whether or not it is a predetermined timing in the symbol variation in which one of the pending change success effect and the pending change failure effect is executed. If Yes in step 5825, in step 5826, the CPUSC of the sub-control board S turns on the hold change execution start flag (a flag that is turned on when the execution timing of the hold change success effect or the hold change failure effect is reached). To do. Next, in step 5827, the CPUSC of the sub-control board S determines whether or not the pending change execution start flag is on. If Yes in step 5827, in step 6050, the CPUSC of the sub control board S executes a pending change execution process, which will be described later, and shifts to the process of step 5830. Even if No in step 5827, the process proceeds to step 5830. If NO in step 5825, in step 5828, the CPU SC of the sub-control board S determines whether or not the execution timing of the change suggestion display change effect has been reached. Here, in this processing, it is determined whether or not it is a predetermined timing in the symbol variation in which one of the variation suggestion display change success effect and the variation suggestion display change failure effect is executed. If Yes in step 5828, in step 5829 the CPUSC of the sub-control board S executes the variation suggestion display change effect, and proceeds to the processing of step 5830. Here, when the variation suggestion display change effect to be executed is the variation suggestion display change success effect, a character appears, the display mode of the variation suggestion display is changed, and the variation suggestion display change effect to be executed is In the case of the change suggestion display change failure effect, a character appears and the display mode of the change suggestion display does not change. The effect mode of the change suggestion display change success effect is such that the display mode of the change suggestion display changes at a predetermined timing during the execution of the symbol change, such as the sub input button SB. The display mode of the variation suggestion display is configured to change without the operation of the operation member. Further, in the case of No in step 5828, the CPU SC of the sub control substrate S determines in step 5840 whether or not the display timing of the chance eye has been reached. If Yes in step 5840, in step 5841 the CPUSC of the sub-control board S executes the display of the chance and the process proceeds to step 5830. Even if No in step 5840, the process proceeds to step 5840.

Next, in step 5830, the CPU SC of the sub control board S determines whether or not the main game symbol is stopped and displayed. If Yes in step 5830, in step 5831, the CPUSC of the sub-control board S sets a stop display command (decision display command) of the decorative pattern (transmitted to the sub-sub-control section SS side in the display command transmission control process of step 5999). Be done). Next, at step 5832, the CPUSC of the sub control board S stops and resets (zero-clears) the mounting variation time management timer. Next, in step 5834, the CPUSC of the sub-control board S turns off the symbol variation flag and shifts to the next processing (processing of step 5900). Even if No in step 5810 or step 5830, the process moves to the next process (process in step 5900).

Next, FIG. 76 is a flowchart of the pending change execution process according to the subroutine of step 6050 of FIG. First, in step 6052, the CPUSC of the sub-control board S determines whether or not the holding change in-execution flag (a flag that turns on at the timing when the holding change success effect or the holding change failure effect is turned on) is off. To do. If Yes in step 6052, in step 6054, the CPUSC of the sub control board S turns on the pending change execution flag. Next, in step 6056, the CPU SC of the sub-control board S displays the character as a pending change agitation effect. Next, in step 6058, the CPU SC of the sub control board S displays a button image prompting the operation of the sub input button SB. Next, in step 6060, the CPU SC of the sub-control board S sets a predetermined value (for example, 3 seconds) to the change effect timer (decrement timer) to start, and proceeds to step 6062. Even if No in step 6052, the process proceeds to step 6062.

Next, in step 6062, the CPU SC of the sub control board S determines whether or not the sub input button SB has been operated. If Yes in step 6062, the process moves to step 6066. On the other hand, if No in step 6062, in step 6064 the CPU SC of the sub control board S determines whether or not the timer value of the change effect timer is 0. If Yes in step 6064, the process moves to step 6066. Next, in step 6066, the CPU SC of the sub-control board S changes the hold to an effect that the character changes the hold in the case of the hold change success effect, or in the case of the hold change failure effect, the character changes to the hold change. Perform a production that fails. Next, in step 6068, the CPUSC of the sub-control board S turns off the pending change execution flag. Next, in step 6070, the CPUSC of the sub-control board S turns off the pending change effect execution start flag, and proceeds to the next process (process of step 5830). Even if No in step 6064, the process proceeds to the next process (process in step 5830). As described above, in the present embodiment, the button image prompting the operation of the sub input button SB is displayed at the time of executing the hold change, and the sub input button SB is operated while the button image is displayed (3 seconds), or When the display period of the button image ends (3 seconds elapse), the change of the hold is executed in the case of the hold change success effect. It should be noted that, when the display period of the button image ends without operating the sub input button SB, the hold change may not be executed.

Next, FIG. 77 is a pending change execution image diagram in the present embodiment. First, the decorative design corresponding to the first main game design is variably displayed. In this example, the number of holds is three, and the trigger hold related to the hold change is the second hold (in other words, after two fluctuations of the symbol change, the symbol change related to the trigger hold is executed. Be done). The display mode of the trigger hold is "white".

Next, a character (a lion in this example) is displayed as a pending change incentive effect, and a button image that prompts the operation of the sub input button SB is displayed.

Next, after the character and the button image are displayed, if the sub input button SB is not operated within a predetermined time (3 seconds in this example), the character and the button image disappear, and the display mode of the hold is It does not change (the display mode of the hold is maintained as "white").

On the other hand, if the sub input button SB is operated before a predetermined time (3 seconds in the present example) after the character and the button image are displayed, the pending change (success) or the pending change effect (success) Either is executed. When the hold change (success) is executed, as the effect of changing the hold by the character, the lion touches the hold display related to the trigger hold, and the effect of changing the hold display mode from “white” to “red” is executed. .. When the hold change (failure) is executed, as the effect of the character failing the hold change, an effect of causing the lion to shed tears is executed, and the hold display mode does not change (the hold display mode remains “white”). Maintained).

Here, in the present embodiment, as an effect mode of the hold change, a hold change inclining effect through an operation of the sub input button SB (an effect including an effect that prompts an operation of the sub input button SB) and an operation of the sub input button SB. And (holding change agitation effect that does not include an effect that prompts the operation of the sub input button SB), and a hold change agitation effect that does not involve the operation of the sub input button SB at the start of fluctuation does not occur. Even in the case of changing, since the effect of prompting the operation of the sub input button SB is suddenly executed during the change, the player can expect a pending change at a plurality of timings. Further, by providing a plurality of effect aspects related to the hold change, various effects can occur in the period from the occurrence of the hold until the symbol variation related to the hold is started, which makes the game entertaining. It is possible to further improve.

Next, FIG. 78 is a flowchart of special game-related display control processing related to the subroutine of step 5900 of FIG. First, in step 5902, the CPU SC of the sub control board S determines whether or not the special game flag is off. If Yes in step 5902, in step 5904, the CPU SC of the sub control board S determines whether or not the special game start display instruction command has been received from the main side. If Yes in step 5904, in step 5912, the CPU SC of the sub-control board S turns on the special game flag. Next, in step 5914, the CPUSC of the sub-control board S sets a command relating to the big hit start display, and proceeds to step 5916. On the other hand, if No in step 5902, the process moves to step 5916.

Next, in step 5916, the CPU SC of the sub control board S sets a command for sequentially displaying the number of rounds and the number of winning prizes. Next, in step 5926, the CPU SC of the sub control board S determines whether or not a special game end display instruction command has been received from the main side. If Yes in step 5926, in step 5928, the CPU SC of the sub-control board S sets a command related to big hit end display on the effect display device SG (displays appropriately based on the kind of big hit). Next, in step 5930, the CPUSC of the sub-control board S turns off the special game flag and shifts to the next processing (processing of step 5999). Even if No in step 5904 or step 5926, the process moves to the next process (process in step 5999).

<Game state transition diagram>
Next, the transition of the main game state in the present embodiment will be described using FIG. 79.

First, in a normal time (low probability/low base), it becomes a big hit (big bonus or normal bonus) with the first special symbol (first main game symbol), and high probability/high base (standby mode, or some hits save time) Mode), high probability or low probability/high base (time saving mode).

In addition, the big bonus is a big hit that wins the battle production during the big hit and shifts to the standby mode which is a high probability/high base, and the normal bonus is a big hit that is drawn or defeated in the battle presentation during the big hit. It is a big hit to shift to the time saving mode, which is either probability/high base or low probability/high base.

In the high base state, the distribution member FB of the auxiliary game electric accessory E10 is in the second mode during most of the time when the auxiliary game electric accessory E10 is in the easy ball entry state (during opening), and the game ball is It becomes easy to enter the first opening entrance N1, and when the game ball enters the first opening entrance N1, the first non-electric accessory HD-1 opens (see FIG. 26).

When a game ball enters the first non-electric accessory HD-1 (first main game starting opening A10-2), the first special symbol starts, so it is true or false in the first special symbol (first main game symbol). A lottery will be held.

As described above, in the pachinko game machine of the present embodiment, in a normal time (low probability/low base), even if any of the big hits, it becomes a high base state after the big hit ends, and even after it becomes a high base state. , It becomes a game state in which a winning/winning lottery mainly based on the first special symbol is performed.

Next, in high probability / high base, you win the big hit with the first special symbol, when the big hit fluctuation starts, the game state is changed from high base to low base, and it becomes high probability / low base (See steps 1419-1 to 1419-3 in FIG. 30).

Here, since the game machine in the present embodiment is capable of parallel lottery, even if the first special symbol (sometimes referred to as the first main game symbol) is changing, the second special symbol (second) The winning/winning lottery and variation due to the main game symbol) are possible, so the game state is changed to the winning/winning lottery by the second special symbol.

Specifically, in the low base, the distribution member FB of the auxiliary game electric accessory E10 is in the first mode during most of the time when the auxiliary game electric accessory E10 is in the easy entry state (during opening). (Refer to FIG. 26), the game ball easily enters the second opening entrance N2, and when the game ball enters the second opening entrance N2, the second non-electric accessory HD-2 Open.

When a game ball enters the second non-electric accessory HD-2 (second main game starting opening B10), the second special symbol is started, so the winning/missing lottery in the second special symbol (second main game symbol) Done.

High probability / low base (while the big hit of the first special symbol is changing), when the game ball enters the second main game starting opening B10, the change of the second special symbol is performed, the variation time of the second special symbol Is configured such that a relatively short time (in this example, small hit: 1.5 seconds, loss: 1.5 seconds) can be easily selected (while the big hit of the first special symbol changes) The lottery result of the second special symbol that started to fluctuate will not be a big hit).

Even if a game ball enters the second main game starting opening B10 with a low probability/low base, the variation time at the time of small hit and loss is long (240 seconds in this example), It is structured so that it will be difficult to continue the lottery. That is, in the high probability / high base state, when the big hit variation of the first special symbol starts, the auxiliary game electric short time flag is turned off at the start of the variation and the opening mode of the auxiliary game electric auditors' product E10 changes, but the main game The time saving flag is maintained (or changed to the main game time saving flag corresponding to the high probability/low base), so as to determine the change pattern relating to the change display of the second special symbol, during the big hit change of the first special symbol. Is configured so that short-term fluctuations can be easily selected.

With this configuration, in the high probability/low base, when the first special symbol continues to change the big hits, the winning/discarding lottery (lottery that causes a small hit or a loss) by the second special symbol is performed a plurality of times. Is configured to be possible.

As shown in the main game table 1 of FIG. 31, the second special symbol is configured to win a small win (approximately 1/1.03), and the second in the high probability/low base (rush mode). Since the fluctuation pattern of the special symbol at the time of a small hit is set to a short time (1.5 seconds in this example), the small hit is frequently generated. (In FIG. 31, the probability of winning the big jackpot is shown as the second main game win/loss table, but in the high-probability/low-base state in which the first special symbol is changing the big jackpot, Even if it is a random number within the range of random numbers, it will be controlled so as to result in a lottery result.

In the case of a small hit, the big winning opening for small hits (the second big winning opening C20) is opened and closed in an open pattern of 1.8 seconds open → closed, and roughly 3 balls are entered during this period (the game ball is the second (When continuously firing toward the special winning opening C20). Therefore, 3 (balls)×5 (prize balls)=15 balls can be obtained by one small hit. (Note that, as shown in FIG. 1, the auxiliary gaming electric role object E10, the first non-electric role object HD-1, the second non-electric role object HD-2, and the like are shown upstream of the second special winning opening C20. Considering that the number of game balls that can be reached is limited as shown in FIG. 83 because obstacle nails and the like are arranged, the opening mode of the second special winning opening C20 may be set to be opened multiple times or one ball may be opened. The number of prize balls per hit may be set to 15, and the design value may be changed as appropriate, for example, one ball entered in one small hit (the winning of 15 prize balls) is set as the design value.)

That is, as will be described later in detail, since the period of high probability/low base (rush mode) is determined by the variation time of the big hit variation of the first special symbol, the longer the variation time of the big hit variation of the first special symbol is, It is configured so that the period during which the coin can be won is extended by the small hit of the second special symbol.

On the other hand, in high probability or low probability/high base (time saving mode), if the actually determined gaming state is high probability/high base, the first special symbol wins the big hit and the big hit fluctuation starts. When you play, you will have a high probability/low base and enter rush mode.

In high probability or low probability/high base (time saving mode), when the actually determined game state is high probability/high base, and when the predetermined number of time saving (30 times or 60 times) is reached, The production mode shifts to the standby mode while the gaming state remains the high probability/high base state.

Also, in the high probability or low probability/high base (time saving mode), when the actually determined game state is the low probability/high base, the predetermined number of times saving (30 times or 60 times) is reached. If it does, shift to normal time (low probability/low base).

In the rush mode, a predetermined small special symbol small hit symbol stop period (small hit start demo time 0.1 seconds + small hit open time 1.8 seconds + small hit end demo time 0.1 seconds = 2 Second), in other words, during the operation of the special electric auditors that the second special winning opening C20 will be opened (during the small hit game), the big hit fluctuation of the first special symbol is temporarily stopped, and the stop period of the small hit symbol When ends, the jackpot fluctuation is restarted.

Next, when the big hit fluctuation of the first special symbol is stopped, if the fluctuation of the second special symbol (displacement fluctuation or small hit variation) is changing, it is forcibly stopped by the miss symbol, and in the big hit of the first special symbol. Big hit production (round battle) is started.

If you win in the big hit production (round battle) in the big hit of the first special symbol, it shifts to high probability/high base (standby mode), and if you lose in the big hit production (round battle), high probability or low probability/high base Move to (time saving mode).

By configuring in this way, the rush mode in which small hits frequently occur continues for the fluctuation time of the first special symbol, so that the rush mode continuation period does not depend on the big hit probability and can secure a certain period. It will be possible.

<Characteristics of fluctuation pattern>
Next, the variation time of the jackpot variation of the first special symbol in the high probability/high base, which is the period of high probability/low base (rush mode) described above with reference to FIG. 33, will be described.

In the big hit symbol α2 in the setting 3 in the present embodiment, when the variation pattern random value is 0 to 255, the variation mode A20 is selected and the variation time is determined to be 30 seconds. Although details will be described later, the effect in the rush mode is one set (winning).

When the variation pattern random value is 256 to 699, the variation mode A21 is selected and the variation time is determined to be 60 seconds. Rush mode production will be two sets (win).

When the variation pattern random value is 700 to 899, the variation mode A22 is selected, and the variation time is 90 seconds. Rush mode production will be 3 sets (win).

When the fluctuation pattern random value is 900 to 989, the fluctuation mode A23 is selected and the fluctuation time is determined to be 120 seconds. Rush mode production will be 4 sets (win).

When the variation pattern random value is 990 to 1023, the variation mode A24 is selected and the variation time is determined to be 150 seconds. Rush mode production will be 5 sets (win). In addition, the variation mode A24 (150 seconds, per 5 sets) will definitely notify that the big hit symbol will have a high probability of α2 during the big hit change (it is definite to win the round battle during the big hit game). It is configured so that it can be selected only when.

In addition, the jackpot of the random number value of the variation mode A20 in the jackpot symbols α1, α2, and α3 is shown (when α1, the number is 500, when α2 is the number 700, when α3, the number is 256, and the jackpot ends. It can be understood that the variation time of the variation mode A20 (variation time of 30 seconds) is relatively easier to select when the probability is low later, and the variation time is low when the probability is low after the big hit ends. It can be said that the short variation pattern is configured to be relatively easily selected. In other words, it can be said that the variation pattern having a long variation time is relatively easy to be selected when the probability of the variation after the big hit is high.

Next, an example of the variation pattern selection ratio according to the set value will be described with reference to FIG. 34. Here, the variation mode determination lottery table of the settings 1 to 3 in the big hit symbol α1 will be described.

First, in the variation mode determination lottery table of the big hit symbol α1 in the setting 3, when the variation pattern random value is 0 to 499, the variation mode A20 is selected and the variation time is set to 30 seconds.

When the fluctuation pattern random value is 500 to 699, the fluctuation mode A21 is selected and the fluctuation time is determined to be 60 seconds.

When the variation pattern random value is 700 to 899, the variation mode A22 is selected, and the variation time is 90 seconds.

When the variation pattern random value is 900 to 1023, the variation mode A23 is selected, and the variation time is determined to be 120 seconds.

The variation mode A24 is not selected. (The big hit symbol α1 is a high probability/high base state as a gaming state after the big hit game, but the effect mode shifts to the time saving mode, and the effect display is not the standby mode, but the effect display for the time saving mode, In order to execute the effect of shifting to the standby mode at the 30th variation or the 60th variation after the big hit game, which is suggested to end the apparent time saving mode, the high probability state transition is definitely notified 5 In order not to execute the set eye.)

Next, in the variation mode determination lottery table of the big hit symbol α1 in the setting 2, when the variation pattern random value is 0 to 599, the variation mode A20 is selected and the variation time is determined to be 30 seconds.

When the variation pattern random value is 600 to 699, the variation mode A21 is selected and the variation time is determined to be 60 seconds.

When the variation pattern random value is 700 to 899, the variation mode A22 is selected, and the variation time is 90 seconds.

When the variation pattern random value is 900 to 1023, the variation mode A23 is selected, and the variation time is determined to be 120 seconds.

The variation mode A24 is not selected.

Next, in the variation mode determination lottery table for the big hit symbol α1 in the setting 1, when the variation pattern random value is 0 to 699, the variation mode A20 is selected and the variation time is set to 30 seconds.

When the variation pattern random value is 700 to 799, the variation mode A21 is selected and the variation time is determined to be 60 seconds.

When the variation pattern random value is 800 to 899, the variation mode A22 is selected and the variation time is set to 90 seconds.

When the variation pattern random value is 900 to 1023, the variation mode A23 is selected, and the variation time is determined to be 120 seconds.

The variation mode A24 is not selected.

As described above, in the case of setting 1, the variation mode A20 in which the variation time is short is relatively easy to be selected, and in the case of setting 3, the variation mode A20 in which the variation time is short compared to the setting 1 and the setting 2. Is relatively difficult to select.

That is, the higher the set value (high setting), the easier the variation mode (variation pattern) with a longer variation time is selected, and the lower the setting value (low setting), the shorter the variation time (variation pattern). Since it is configured to be relatively easily selected, it is possible to solve the problem that in the conventional small hit frequent occurrence mode, the higher the setting, the larger the big hit is, and the small hit frequent occurrence mode is likely to end. The profit can be increased in the small hit frequent occurrence mode as the setting is made.

<High probability/low base (rush mode) fluctuation control>
Next, the fluctuation control in the high probability/low base will be described with reference to FIG.

First, as described above, in the high probability/high base (standby mode), a big hit is won in the first special symbol, and the high probability/low base (rush mode) is started by starting the big hit variation.

In the high probability/low base (rush mode), it becomes easy to enter the second main game starting opening B10, the second special symbol frequently changes, and it is almost a small hit (about 1/1.03).

In FIG. 80, after entering the high probability/low base (rush mode), the first change of the second special symbol is performed. Since the first change is a small hit change, it stops in 1.5 seconds and the special winning opening for small hits (the second special winning opening C20) is opened for 1.8 seconds. The period when the small hit symbol is stopped and displayed (small hit start demonstration time 0.1 seconds + second big winning opening opening time 1.8 seconds + small hit end demo time 0.1 seconds = total 2 seconds) is the first The big hit variation of the special symbol is interrupted, and after the period (2 seconds) in which the small hit symbol is stopped and displayed, the next variation of the second special symbol becomes possible and the big hit variation of the first special symbol is restarted.

Immediately after that, the fluctuation of the second special symbol has started. The variation is a loss, stops at 1.5 seconds, and because of the loss, the second special winning opening C20 is not opened but remains closed. At this time, the fluctuation of the big hit of the first special symbol is not temporarily stopped, but the fluctuation is continued.

That is, when the second special symbol is a small hit, the big hit variation of the first special symbol is temporarily stopped, but when the second special symbol is lost, the big hit variation of the first special symbol is not temporarily stopped. ing. Therefore, the more you win the small hit in the second special symbol, the period of high probability / low base (rush mode) (the period from when the variation display of the big hit variation of the first special symbol is switched to the stop display) is It will be long.

<Number of winnings in rush mode>
Next, the number of coins won in the high probability/low base (rush mode) will be described.

As shown in FIG. 35, the variation time of the small hit variation pattern (variation aspect B20) and the variation variation pattern of the second special symbol (variation aspect b3) in the high probability/low base (rush mode) are both 1.5. Seconds.

Since the big hit fluctuation of the first special symbol is interrupted during the small hit, the number of winning coins in the high probability/low base (rush mode) can be calculated by the following formula.
[formula]
(1st special symbol big hit change time / small hit change time) × 1 small hit prize ball expectation × small hit winning probability

For example, when using the case where the first special symbol big hit variation time is 150 seconds, it is applied,
(150 (seconds)/1.5 (seconds))×{3 (number of balls entered)×5 (number of prize balls of the second big winning opening C20)}×(1/1.03)
=100×15×0.97...
≈ 1456 (pieces)
Therefore, if the variation time of the first special symbol jackpot is 150 seconds, it is possible to obtain 1456 coins in the high probability/low base (rush mode).

In this example, the number of coins to be won per jackpot is 10 (count)×10 (round)×15 (the number of prize balls of the first big winning opening C10)=1500 (pieces) In terms of design value, the number of coins that can be won once per jackpot (1500) is higher than the maximum number of coins that can be won (about 1456) in a high probability/low base (rush mode). ing.

With this configuration, it is possible to win a maximum of about two big hits by the small hit and the big hit in the rush mode, but the small hits occur frequently and the big hits are won. It is preferable that the number of coins that can be obtained in the possible game state is designed to be smaller than the number of coins that can be obtained in one big hit. In addition, in the above-mentioned calculation formula, after the variable display which is the loss of the second special symbol, the stop display fixed time provided to show that the player has been lost is not calculated in consideration of the time, The stop display fixed time at the time of loss is set to 0.5 seconds, the variation time of the loss variation of the second special symbol in the high probability/low base state is set to 1.0 second, and the like, at the time of a small hit and the loss. The consumption may be designed to be the same during the rush mode period depending on time.

<High probability/low base (during rush mode) loss probability>
Next, the high-probability/low-base (during rush mode) loss probability will be described with reference to FIG.

As described above, the present embodiment is capable of parallel lottery, but is configured so as not to be a big hit in both the first special symbol and the second special symbol at the same time.

Specifically, in the high probability/low base, the lottery is mainly performed in the first special symbol. If you win the big hit in the first special symbol, the lottery process is executed after the win/win lottery result of the first special symbol is executed in the second special symbol. If the big hit is selected, the big hit is selected. After that, it is forcibly rewritten to lose (If the other special symbol is determined to be a big hit, it may be configured to draw in a lottery table that does not win the big hit. Any method may be used as long as it can be controlled so that the fluctuations that are a big hit at the same time are not executed).

For example, when the high probability of the second special symbol in the setting 1, random number value 0-63499: small hit, random number value 63500-65344: big hit, random number value 65345-65535: lost, big hit in the first special symbol Then, when the random number value 63500 to 65344: big hit is won, it is rewritten as a loss. That is, the random number values 0 to 63499 are small hits, and the random number values 63500 to 65535 are loss.

Similarly, when the high probability of the second special symbol in the setting 3, random number value 0-63499: small hit, random number value 63500-65479: big hit, random number value 65480-65535: lost, big hit in the first special symbol If winning, random number value 63500 to 65479: big hit, if it wins, it is rewritten as lost. That is, the random number values 0 to 63499 are small hits, and the random number values 63500 to 65535 are loss.

That is, regardless of the set value, the random number values 63500 to 65535 are lost, but if the range was originally a big hit, that is, because the first special symbol is a big hit, rewrite from big hit to lose In such a case, an effect (for example, light emission of a predetermined lamp) suggesting the set value may be performed so that the player can estimate the set value.

With such a configuration, the higher the setting, the larger the range of the big hit originally, so that it is possible to easily generate the effect suggesting the set value. Furthermore, if limited to the case where the random number range that is a big hit is originally lost, the execution frequency of the production that suggests the installation value during the rush mode becomes the same as the big hit probability in the normal time, and even during the high probability state It is possible to set an effect that occurs with the same probability as a jackpot of, and to create an event that can occur with one probability according to the set value across high probability states and normal times, and even in high probability states It is possible to provide information useful for estimating the jackpot probability of (the number of executions of the effect that suggests a set value, which is information that substitutes for the number of jackpots at normal times). As a modified example, not only the range that is originally a big hit, but also a variation in loss according to a random number in the range of 63500 to 65535 that is a loss regardless of the set value, a notice that suggests a similar set value is executed. You may.

<Opening pattern of electric accessory and variation time of special figure in low probability/high base>
Next, a case where a big hit with the first special symbol during the low probability/high base is described.

First, during the low probability/high base, the opening pattern of the auxiliary game electric accessory E10 is 0.2 second open→1.6 second closed→5.8 second open→closed (if necessary, 26).

If you win the big jackpot with the first special symbol in the low probability / high base, it will become a low probability / low base because it changes from a high base to a low base when the big hit fluctuation starts (from step 1419-1 in FIG. 30. See step 1419-3). In the low probability/low base, the opening pattern of the auxiliary game electric accessory E10 is 1.6 seconds open→0.2 seconds closed→0.2 seconds open→closed.

In other words, it is possible to observe the opening pattern of the auxiliary game electric auditors role object E10 in the low probability/high basis, and to understand that the low probability/low base is achieved at the timing when the opening pattern of the auxiliary gaming electric role object E10 is changed. Yes, it is possible to know that you have won the jackpot.

Further, since the effect display device SG is configured to display "right hitting" when the base is high, it is possible to grasp whether or not the jackpot is won also in the display. In other words, if you win the big hit with the first special symbol in the low probability / high base, when it becomes the low probability / low base, the "right hit" display will be erased or "left hit" will be displayed To be done.

Therefore, when the first special symbol in the low probability/high base becomes a big hit, it is possible to make the player interested in performing the effect of inspiring the result in the long variation pattern (variation mode in which the variation time is long). May not connect very well.

Therefore, in the present embodiment, the big hit variation pattern (variation mode A10) of the first special symbol in the low probability/high base is configured to be a short time (3 seconds) so that the big hit game is started immediately, and an auxiliary game The configuration is such that it is not necessary to observe the opening pattern of the electric accessory E10 or the display of "right hitting".

Even if you win the big hit with the 1st special symbol on a low probability/high basis, the display of "Right hit" will continue, and the specification of "Please hit left" may not be displayed. ..

A display indicating by the CPU MC of the main control board M whether to hit left or right (for example, when a predetermined LED is lit, it indicates that right should be hit, When it is turned off, it indicates that the player should left-handed), and in normal times (for example, when the main game probability change flag, the auxiliary game shortened flag, and the special game execution flag are all off), left-handed must be always used. It is configured to suggest that there should be a right hit at all times other than the normal time (for example, when at least one of the main game probability change flag, the auxiliary game time saving flag, and the special game execution flag is on). Is appropriate.

<High probability/high base (standby mode) display screen>
Next, a high-probability/high-base (standby mode) display screen will be described with reference to the upper diagram of FIG.

In the high probability / high base (standby mode), the effect display device SG,
1. 1st special design Resident decoration design (sub-decoration design) ⇒ Lower left side of LCD screen 2. Second special design Resident decorative design (sub-decorative design) ⇒ lower left side of the LCD screen 3. 1st special symbol hold display ⇒ Middle right side of LCD screen 4. Second special symbol Hold display ⇒ Middle right of LCD screen 5. Right-handed instruction display ⇒Upper right side of LCD screen 6. Performance mode display ⇒ Upper left side of LCD screen 7. 1st special design Decorative design (main decorative design) ⇒Approximately the center of the LCD screen 8. Performance meter A ⇒ Lower right side of LCD screen 9. Cumulative number of acquired balls ⇒ Lower right of LCD screen 10. Display of number of consecutive camps ⇒Upper center of LCD screen 11. Big hit result icon (total of big hit payout + rush mode payout) ⇒ is added in the middle of the LCD screen from left to right.

The first special symbol resident decorative symbol (sub decorative symbol) is a decorative symbol that is always displayed among the decorative symbols displayed on the liquid crystal screen while the first special symbol is changing or stopped. The second special symbol resident decorative symbol is a decorative symbol that is displayed on the liquid crystal screen while the second special symbol is changing or stopped, and is a decorative symbol that is always displayed. The first special symbol hold display is a hold number display of the first special symbol displayed on the liquid crystal screen. The second special symbol hold display is a hold number display of the second special symbol displayed on the liquid crystal screen. The right-hit instruction display is a display that is displayed on a high base and that indicates to the player the position at which the game ball should be shot. The effect mode display is a display showing the effect mode in which the user is staying. The first special symbol decorative pattern (main decorative symbol) is a decorative symbol displayed on the liquid crystal screen while the first special symbol is changing or stopped so that it can be easily recognized by the player. is there. The production meter A is a display for indicating the number of sets (=big hit variation time) in the big hit variation of the first special symbol, which will be described in detail later. The cumulative acquired ball number display is a display of the total acquired ball number acquired in the condominium, and the total of the acquired ball number in the jackpot and the acquired ball number in the rush mode is displayed. The number of consecutive holidays display is a display showing the number of times of continuous success of the big hit (number of consecutive holidays). The big hit result icon displays one big hit and one rush mode as one unit, and displays the total number of coins obtained for one big hit and one rush mode for each unit.

The display screen of the standby mode A is displayed until the big hit variation starts with the first special symbol. More specifically, a big hit variation is started in the first special symbol, and a specific symbol (eg, "rush mode" is described in the main decorative symbol region of the effect display device SG or approximately in the center of the effect display device SG. The display screen of the standby mode A is displayed until (pattern) is displayed.

That is, the display of the specific symbol is a trigger to shift to the display screen in the rush mode, and the specific symbol is configured to be displayed about 6 seconds after the big hit variation start of the first special symbol.

In addition, the specific symbol is displayed in the display area of the "7. First special symbol decorative symbol (main decorative symbol)" or substantially in the center of the screen, and the "1. First special symbol resident decorative symbol (sub decorative symbol)" In the display area as well, the specific symbol is displayed with fluctuation.

In addition, in the display area of "1. First special design resident decorative design (sub-decorative design)", it is configured so that the specific design is not displayed, and "7. First special design decorative design (main decorative design)" )” is displayed in the display area or in the approximate center of the screen, the variable display is continuously displayed in the display area of “1. Special special pattern resident decorative pattern (sub decorative pattern)”. It may be configured as follows.

Further, the effect displayed in accordance with the display of the specific symbol may be configured to suggest whether or not the big hit is a probability variation hit. For example, the probability effect probability may be increased in the order of blue effect→green effect→red effect.

<High probability/low base (rush mode A) display screen>
Next, a high-probability/low-base (rush mode A) display screen will be described with reference to the middle diagram of FIG. 81. The rush mode is provided with a rush mode A and a rush mode B, which the player can select by operating the sub input button SB and/or the cross key SB-2. In addition, the effect mode selection of the rush mode is selectable because an effect that can be selected appears when a big hit game that enters the standby mode is being executed (for example, a big hit end demo period). .. Although not shown, in the standby mode when the rush mode B is selected, the production meter A in the standby mode A is replaced with the production meter B and the lamp image shown in the lower diagram, and the standby mode is set according to the mode. A background effect image is displayed.

In the high probability / low base (rush mode A), the effect display device SG,
1. 1st special design Resident decoration design (sub-decoration design) ⇒ Lower left side of LCD screen 2. Second special design Resident decorative design (sub-decorative design) ⇒ lower left side of the LCD screen 3. 1st special symbol hold display ⇒ Middle right side of LCD screen 4. Second special symbol Hold display ⇒ Middle right of LCD screen 5. Right-handed instruction display ⇒Upper right side of LCD screen 6. Performance mode display ⇒ Upper left side of LCD screen 7. Second special pattern Decorative pattern (main decorative pattern) ⇒ slightly above the center of the LCD screen 8. Performance meter A ⇒ Lower right side of LCD screen 9. Cumulative number of acquired balls ⇒ The lower right side of the LCD screen is displayed.

The second special symbol decorative pattern (main decorative symbol) is a decorative symbol displayed on the liquid crystal screen while the second special symbol is changing or stopped so that the player can easily recognize it. is there.

The effect in the rush mode is configured for 30 seconds (maximum 5 sets=150 seconds) for one set, and is configured to execute the continuous fanning effect for each set. When the continuous fanning effect is executed, the display of "7. Second special symbol decorative pattern (main decorative pattern)" is not displayed, and the continuous fanning effect is focused. In addition, one set of "30 seconds" is assumed to be 30 seconds in the elapsed time of the big hit fluctuation of the first special symbol which is to be shifted to the rush mode, and the first special due to the small hit of the second special symbol. If the variable display of the symbols is interrupted (the subtraction of the timer that manages the variable display time is interrupted), the time of "30 seconds" as one set of the rush mode is interrupted similarly to the variable display of the first special symbol. As a production time, one set is a time exceeding “30 seconds”.

In addition, when the display indicates that the set does not continue in the continuous fan production (for example, the ally character loses in the continuous battle production), and the fluctuation stops and a big hit occurs, the decorative symbol of the first special symbol is The specific pattern (the pattern in which the letter “R” indicating that it is in the rush mode is written) is swinging and changed to a display mode indicating a big hit such as “777” and stopped and displayed.

In other words, when the rush mode continues, the rush mode display ⇒ continuous fan production ⇒ continuous fan success display ⇒ rush mode display screen, and when the rush mode ends (variation display time of the big hit fluctuation of the first special symbol) In case of elapse), rush mode display ⇒ continuous fan production ⇒ continuous fan production failure display ⇒ big hit display (eg, "777") ⇒ big hit game.

It should be noted that, in the continuous flairing effect, the set may always be in a special state (for example, the ally character is invincible), and the ally character displayed in the rush mode display is displayed in the special state so that the next continuous flairing effect May be indicated as being continued, or may be configured to indicate that the ally character displayed in the continuous stirring effect is displayed in a special state to be continued in the continuous stirring effect.

<Direction meter A>
Next, the specifications of the performance meter A will be described.

The production meter A is a display used to indicate whether or not the big hit of the first special symbol is a probability variation big hit during the big hit variation of the first special symbol.

Five effect balls can be acquired in the performance meter A, and when the rush mode A is entered, the first effect ball is displayed in blue, and the effect ball is acquired each time the set continues (in the effect ball The color changes). In other words, the first effect ball is blue in the first set, the second effect ball is yellow in the second set, the third effect ball is green in the third set, In the 4th set, the 4th effect ball turns red, and in the 5th set, all the effect balls change to rainbow color.

In the present embodiment, the larger the number of sets (longer variation time), the higher the probability of being a probability variation big hit (see FIG. 33). Therefore, the player increases the number of sets in rush mode A. , It is possible to directly recognize that the probability change probability is increasing each time the color of the effect ball changes, and it is possible to expect a holiday cottage.

Further, using the effect balls (effect balls whose colors have changed) acquired during rush mode A, a probability change notification effect for notifying whether or not there is a probability change during the jackpot effect is performed.

Specifically, as shown in FIG. 82, it is notified whether or not a button effect is generated in a predetermined round (for example, 9 rounds) of the big hit effect and the probability is changed. First, a button image indicating that the button operation is valid is displayed. Next, the effect balls acquired during the rush mode A are collected in the button image. Next, the button is changed according to the degree of chance increase of the button image (for example, the degree of chance increase is indicated by the size and number of flames, or the type of the button image itself is indicated by displaying a high expectation effect button image). Suggests the possibility of successful production. As described above, the larger the number of the obtained effect balls, the easier it is for the button image to have a better chance, and the easier it is for the button effect to succeed.

In the pre-reading process in the high probability/high base (standby mode A), when the big hit variation pattern exists in the first special symbol in the hold, in the variation of the deviation before the variation by the big hit variation pattern is started. The effect balls may be acquired according to the result of the preliminary determination regarding the variation time of the jackpot variation pattern in the hold. In this case, the continuation of the number of sets according to the number of effect balls acquired by the time the rush mode A is started is definitely indicated and notified in advance.

By configuring in this way, the minimum duration of the rush mode can be grasped before the big hit fluctuation actually starts, and the expectation for the number of coins to be won by the small hit during the rush mode can be calculated. It can be increased before the start.

Furthermore, in the same special symbol (for example, only the first special symbol), if there are two jackpots pending, a special effect (for example, an extra bonus) from the start of the jackpot effect by the first jackpot. It is also possible to display and inform that the next big hit is confirmed.

At this time, the second big hit hold is a big hit within the random number range that is a big hit regardless of whether or not the first big hit hold is a probability variation, that is, within the random number range that is a big hit at a low probability. A big hit is preferred. With this configuration, the gaming state after the jackpot related to the first jackpot holding ends is low, and the result of the win/loss lottery related to the second jackpot holding is lost. The situation can be prevented.

In addition, in this example, the color of the effect ball (provisional image of the probability of probability change) is switched stepwise according to the number of sets, and finally it becomes definite after the big hit game that it is definitely 5 sets. Although all the effect balls are configured to be iridescent in the eyes, as a modified example, regarding the image of the effect ball that has already been acquired, the game result in the rush mode (for example, the second big prize based on the small hit of the second special symbol). Executed by entering the game ball into the winning opening C20, executing the variation of the second special symbol, entering the gate or winning opening that can enter when the game ball flows down when you hit the right) Even if a performance lottery is performed in which the production balls are replaced with higher ones (or effects are added to the production balls, etc.) so as to increase the sense of expectation that the fluctuations in the big hits will change after the big hit. Good. By configuring in this way, when increasing the chance of a button effect that occurs in a predetermined round during a big hit, the probability of probability change depends not only on the number of effect balls but also on the combination of the effect balls (or effect images) displayed. Can be made different, and the interest of the game can be enhanced by paying attention also to whether or not the chances of the effect ball increase during the rush mode.

<High probability/low base (rush mode B) display screen>
Next, a high probability/low base (rush mode B) display screen will be described with reference to the lower diagram of FIG.

In the high probability/low base (rush mode B), the effect display device SG is
1. 1st special design Resident decoration design (sub-decoration design) ⇒ Lower left side of LCD screen 2. Second special design Resident decorative design (sub-decorative design) ⇒ lower left side of the LCD screen 3. 1st special symbol hold display ⇒ Middle right side of LCD screen 4. Second special symbol Hold display ⇒ Middle right of LCD screen 5. Right-handed instruction display ⇒Upper right side of LCD screen 6. Performance mode display ⇒ Upper left side of LCD screen 7. 2nd special design Decorative design (main decorative design) ⇒Slightly above the center of the LCD screen 8. Performance meter B ⇒ Right side of LCD screen upper to lower 9. Cumulative number of acquired balls ⇒ Lower right of LCD screen 10. Lamp image ⇒ The upper right side of the LCD screen is displayed.

The production meter B is a display for suggesting the number of sets (=big hit variation time) in the big hit variation of the first special symbol. The lamp image is a display that indicates that the big hit variation is a sure-change big hit by becoming a lighting image.

In the production meter B, the jackpot variation of the first special symbol starts in the high probability/high base (standby mode B), and when the specific symbol is displayed, the charging effect of charging the meter is performed. In the charging effect, the meters are displayed as if they accumulate from bottom to top, and one meter scale indicates one set, and each time the set continues, the scale is reduced by one. There is. It should be noted that with one meter as one set, each time it is charged, a display showing the number of charges such as "x1" and "x2" is displayed, and the number of "x○" decreases by 1 each time the set continues. Alternatively, it may be configured such that a plurality of meters are displayed and one is erased each time the set is continued. That is, the effect meter A is displayed every time the set number continues, whereas the effect meter B displays the set number that continues first.

It should be noted that, when all the charged meters in the effect meter B are exhausted, the recharge effect of recharging the meter (there is a failure pattern in which the meter is not charged) may be configured to be executable. Further, the specific symbol may be a symbol in which the specific symbol in the rush mode A and the specific symbol in the rush mode B are different from each other, and when the specific symbol displayed in the substantially central portion of the main decorative symbol region or the effect display device SG is different. In the rush mode A and the rush mode B, the specific symbol displayed in the display area of the sub-decorative symbol also becomes a different symbol.

Further, in the prefetch process in high probability / high base (standby mode B), if there is a big hit variation pattern in the first special symbol hold, big hit in the variation of the deviation before the variation by the big hit variation pattern is started. The meter may be configured to be chargeable according to the variation time of the variation pattern.

It should be noted that the effect balls obtained in the effect meter A are used in the big hit effect, but the charged meter in the effect meter B is not used in the big hit effect. That is, in the rush mode B, the effect meter B informs the player of the degree of expectation of the winning prize balls in the rush mode, while the degree of expectation regarding the button effect during the big hit is the button effect during the big hit. It is difficult to estimate as a player, and it is difficult to estimate whether or not it is a probability variation big hit from the production meter B (exception when the production meter B is full, or When the situation continues for 5 sets due to recharging, etc., it is possible to predict that there is a probable change before the button performance during the big hit, because the fact that the fluctuation related to the probabilistic big hit is changing is definitely notified. Become).

The ramp image is not only during the charging performance after the display of the specific symbol in the big hit variation, but also during the charging before the start of the big hit variation, to the second big winning opening C20 based on the small hit symbol stop of the second special symbol in the rush mode. It is configured so that a lighted image can be obtained even when the player enters a ball, during a big hit performance, or the like. It should be noted that, during charging before the start of the big hit variation, a lighting image can be a lighting image at the time of entering the second special winning opening C20, etc. The CPUSC of the sub-control board S is surely changed into the first special symbol hold by the prefetching process. When it is recognized that there is a big hit, the big image can be a lighting image during the big hit production, because this big hit is a definite change big hit, and the player is prompted to operate the sub input button SB during the big hit production. Alternatively, the sub input button SB may be operated at a predetermined timing.

<Power failure recovery in rush mode>
When the power is cut off during the high probability/low base (rush mode) and the power is restored, the game state information (high probability/low base) is transferred from the CPUMC of the main control board M to the CPUSC of the sub control board S. Is transmitted, and the CPU SC of the sub-control board S is configured to return to the rush mode based on the received game state information (command indicating high probability/low base).

The rush mode after recovery from power failure is configured to recover in a rush mode A that is predetermined as a default rush mode.

Also, instead of returning to the rush mode based on the received game state information, from the CPUMC of the main control board M to the CPUSC of the sub-control board S, the variation pattern of the second special symbol on a high probability/low base (small hit) Variation pattern: variation mode B20, loss variation pattern: variation mode b3) variation start information or variation stop information is transmitted, the CPUSC of the sub-control board S, the variation pattern of the high probability / low base second special symbol received It may be configured to return to the rush mode based on the variation start information or variation stop information of (small hit variation pattern: variation mode B20, loss variation pattern: variation mode b3).

<Supplemental/Modification example>
When the big hit variation starts in high probability/high base, it becomes high probability/low base, but the display screen in the standby mode is displayed on the effect display device SG until the specific symbol is displayed. At this time, the effect display device SG has a high probability/low base even if the standby mode is displayed, and thus is in a game state in which it is easy to obtain a payout due to a small hit.

At this time (when the standby mode is displayed with high probability/low base), the coins won by the small hit may be configured to be counted as the coins won during the rush mode. Don't count as the coins acquired during the standby mode immediately after the big hit variation related to the special symbol, and count only the coins acquired by the small hit after actually entering the rush mode as the coins acquired during the rush mode. It may be configured to do so.

At this time (when the standby mode is displayed with a high probability/low base), if the number of coins won by the small hit is counted as the coins won in the rush mode, the actual small hit It is possible to count the exact number of coins that have been acquired since the game state in which the coins can be acquired, and only the coins that were acquired by the small hit after actually entering the rush mode can be acquired during the rush mode. When configured to count as balls, it is possible to count the number of coins obtained in the apparent rush mode so as to suit the game.

High probability/high base (standby mode) Even if the first special symbol big hit fluctuation starts when it shifts to high probability/low base, it is already changing when the first special symbol big hit fluctuation starts. If the variation of the second special symbol (in case of small hit: variation mode B10/variation time 10 seconds, in case of loss: variation mode b2/variation time 10 seconds) is not completed, a high probability/low new base The second special symbol will not be drawn.

That is, when the fluctuation of the second special symbol starts immediately before the big hit fluctuation of the first special symbol starts, about 10.0 seconds (the second special started just before the big hit fluctuation of the first special symbol starts The variation time of the symbol is 10 seconds), which means that at least a small hit does not occur.

In the present embodiment, the specific symbol is displayed 6 seconds after the start of the big hit fluctuation of the first special symbol, and the rush mode is entered, so that even if the rush mode is entered, about 4 seconds, Even if a game ball enters the second main game starting opening B10 based on the variation, the lottery is not performed, and the player may feel uncomfortable.

Therefore, in the high probability/high base (standby mode), when the big hit variation of the first special symbol is started, the specific symbol is displayed by the second special within 6 seconds after the start of the big hit variation of the first special symbol. If the fluctuation of the symbol can be started, it is 6 seconds after the start of the big hit fluctuation of the first special symbol, and the fluctuation of the second special symbol cannot be started within 6 seconds after the start of the big hit fluctuation of the first special symbol. (When the remaining variation time of the second special symbol is 6 seconds or more at the start of the jackpot variation of the first special symbol), the specific symbol is displayed at the variation end timing of the second special symbol, and the rush mode is entered. It may be configured as follows. With this configuration, after the specific symbol is stopped and displayed, the effect indicating that the second special symbol is a small hit (for example, the main decorative symbol of the second special symbol is stopped and displayed in a small hit mode) It is configured so that the period until the occurrence of) does not become excessively late, and the loss feeling for the remaining time of the rush mode based on the fluctuation of the second special symbol that started fluctuation before the jackpot fluctuation of the first special symbol started. I am trying to reduce it.

<Ratio of playing balls>
Next, with reference to FIG. 83, the ratio of the flow of the game balls when hitting to the right will be described. Here, for each game state, a configuration designed on the assumption of which route and how many balls should flow when 100 game balls are shot is shown. In addition, although not shown, the game balls have their fall routes sorted by opening and closing of each electric accessory, nails and the like.

First, the high base (standby mode/time saving mode) of (a) will be described.

First, when hitting to the right, all (100 balls) game balls reach above the auxiliary game starting port H10.

Next, 99 balls of them are directed to the auxiliary game starting port H10, and one ball is directed in a direction different from that of the auxiliary game starting port H10.

Among the game balls that have passed through the auxiliary game starting port H10 (here, the gate), the high base state makes it easy to enter the auxiliary game electric accessory E10, so 50 balls to the auxiliary game electric accessory E10. Toward the direction of entering the ball, 49 balls do not enter the auxiliary game electric accessory E10, but join the falling route of one ball that did not go to the auxiliary game starting opening H10 (enter the auxiliary game electric accessory E10 Not 50 game balls in total. In the high base state, most of the game balls that have entered the auxiliary game electric accessory E10 are configured to enter the first opening entrance N1 by the action of the sorting device FS, but rarely 2 Enter into the open entrance N2.

Of the 50 balls that have joined, 19 balls will be directed toward the upper outlet D36-2, 30 balls will be directed toward the first non-electric accessory HD-1, and 1 ball will be in the other direction. Head to. When the game ball enters the first non-electrical accessory HD-1, the weight of the game ball shifts to the closed state, and the first open ball entrance N1 in the auxiliary game electric accessory E10 is used again for the game ball. If does not pass, the closed state will be maintained, so in reality, most of the 30 game balls that have flowed down toward the first non-electric accessory HD-1 flow down further downstream.

The game ball that has not entered the first non-electrical accessory HD-1 when the first ball and the first non-electrical accessory HD-1 that are directed in the other direction are in the closed state is the second special winning opening C20. It flows down toward (the big winning hole for small hits), the second non-electric accessory HD-2, and the first big winning hole C10 (big winning hole for big hits). At this time, the second non-electric accessory HD-2 is not in the open state, and the second special winning opening C20 is not in the open state (opening based on the small hit of the second special symbol) (FIG. 83(a)(c). ) Indicates a state in which the second special winning opening is closed), and the player will enter the lower outlet D36 without entering those entrances.

Next, the high probability/low base (rush mode) of (b) will be described.

First, when hitting to the right, all (100 balls) game balls reach above the auxiliary game starting port H10.

Next, 99 balls of them are directed to the auxiliary game starting port H10, and one ball is directed in a direction different from that of the auxiliary game starting port H10.

Among the game balls that have passed through the auxiliary game starting opening H10 (here, the gate), it is more difficult to enter the auxiliary game electric accessory E10 than the high base state because it is in the low base state, and 20 balls Heading toward the auxiliary game electric accessory E10, 79 balls do not enter the auxiliary game electric accessory E10, and join the falling route of one ball that did not go to the auxiliary game starting opening H10 (auxiliary game (A total of 80 game balls that do not enter the electric accessory). In the low base state, most of the game balls that enter the auxiliary game electric accessory E10 are configured to enter the second opening entrance N2 by the action of the sorting device FS, but rarely 1 Enter the open entrance N1.

Of the 80 balls that have joined, 19 balls will go to the direction of entering the upper outlet D36-2, and 61 balls will go to the other direction.

The 61 balls that went in the other direction went to the direction where 15 balls entered the second big winning opening C20 (small winning big winning opening) (in FIG. 83(b), the second big winning opening was opened). 20 balls toward the second non-electric accessory HD-2, and 26 balls into the first big winning opening C10 (big winning opening for big hits). The player will enter the lower outlet D36 without playing. When the first non-electrical accessory HD-1 is open, a part of the 61 balls heading in the other directions will enter the first non-electrical accessory HD-1. ..

Next, the mid-hit of (c) will be described.

First, when hitting to the right, all (100 balls) game balls reach above the auxiliary game starting port H10.

Next, 99 balls of them are directed to the auxiliary game starting port H10, and one ball is directed in a direction different from that of the auxiliary game starting port H10.

Among the game balls that have passed through the auxiliary game starting opening H10 (here, the gate), it is difficult to enter the auxiliary game electric auditors' product E10 because it is in a low base state, so 20 balls are the auxiliary game electric auditors' object E10. 79 ball toward the person who does not enter the auxiliary game electric accessory E10, and joins with the falling route of one ball that did not go to the auxiliary game starting opening H10 (to the auxiliary game electric object) (A total of 80 game balls for those who do not enter).

Of the 80 balls that have joined, 19 balls will go to the direction of entering the upper outlet D36-2, and 61 balls will go to the other direction.

The 61 balls that went to the other, went to the second non-electric auditors HD-2 to enter 20 balls without entering the second special winning opening C20 (small winning big winning opening), and then If the 1 big winning opening C10 is open, 41 balls go to the direction of entering the 1st big winning opening C10 (big winning opening for big hits), and if the 1st big winning opening C10 is closed, 41 balls The player will enter the lower outlet D36. Although not shown in the drawing, in a normal time (low probability/low base), when the player hits to the right, he/she flows down along the same path as a big hit (while the first special winning opening C10 is closed).

<<Explanation of level-up production (pre-reading production/variable production)>>>
Next, a level-up effect, which is one of the effect modes of the gaming machine, will be described.

The level-up effect is an effect that can be executed in any of the look-ahead effect (an effect that suggests whether or not the pending state is unchanged) and the variable effect (an effect that suggests whether or not the change is fluctuating during change). In this example, A configuration in which the level of a stage (also referred to as a production stage, a mode, a production mode, etc.) displayed on the production display device SG is increased will be exemplified. It should be noted that shifting to a higher level stage as the level increases suggests that the jackpot expectation is increasing.

<Transition of stage and stage level>
Next, transitions between stages and stage levels will be described with reference to FIG.

In this example, four stages of stage A, stage B, stage C and stage D are provided as stage level 1 (Lv1), and three stages of stage AA, stage BB and stage CC are provided as stage 2 of stage level 2. As the third stage, one stage of stage XXX is provided.

The three stages of stage A, stage B, and stage C in the stage level 1 are selected when the CPUSC of the sub-control board S wins a stage change lottery executed with a predetermined probability for each variation, or a predetermined number of variations in the same stage (for example, (20 fluctuations) When the user stays, the stage is changed to a stage different from the stage he was staying. It should be noted that stage D is a stage in which transition is made after the time-saving mode is completed and stays up to 15 fluctuations. Determined by

Stages A, B, and C are configured such that different notices can be executed for each stage, and further, a stage background image, a display mode of a decorative design (characters, numbers, etc.), a variation mode of the decorative design, etc. It is configured to be different for each stage. Examples of notices that differ for each stage include normal notices (step-up notices, dialogue notices, and other notices that occur mainly before reach).

The three stages of the stage AA, the stage BB, and the stage CC in the stage level 2 (Lv2) are provided as the stages to be upgraded from the corresponding stage level 1. Specifically, the stage AA is upgraded from the stage A, the stage BB is upgraded from the stage B or the stage D, and the stage CC is upgraded from the stage C. Therefore, there is no transition to another stage of the same stage level, such as between the three stages of stage A, stage B, and stage C of stage level 1.

The stage AA, the stage BB, and the stage CC are configured so that the same advance notice as the stage before the level up is executed. For example, in stage A and stage AA, a common normal notice can be executed. Further, the display mode (characters, numbers, etc.) of the decorative design, the variation mode of the decorative design, etc. are configured in the stage level 2 in common. The stage background image is a background image that differs for each stage.

The stage A and the stage AA may have different stage background images, or may have the same stage background image and at least different character displays (effect mode display) indicating the stay stage.

The stage XXX in the stage level 3 (Lv3) is the highest level stage, and is configured to be able to shift from any stage.

It is preferable that at least the characters "stage XXX" are displayed so that it can be recognized that the stage XXX is different from any other stage. It should be noted that the same notice as in stage level 1 and stage level 2 may be executed, or different notice may be executed. Further, in the case where the characters “Stage XXX” are not displayed on the stage XXX, it is preferable to visually differentiate from other stages so that the player can visually recognize and recognize that the stage is XXX. Is.

When the same notice as in stage level 1 and stage level 2 is configured to be executed, it is easy for the player to feel the expectation for a jackpot by making the notices of the same mode can occur consecutively. It can be configured. When a notice different from the stage level 1 and the stage level 2 is configured to be executed, it is easy to recognize the notice that can be generated only in the stage level 3 so that the player can expect a big hit. The configuration can be made easy.

<Stage level up within 1 fluctuation>
Next, the timing for raising the stage level within one fluctuation will be described with reference to FIG.

First, the timing of the level up of the stage in the period from the start of the fluctuation to the tempering (reach) will be described.

First, when the fluctuation starts, the first timing at which the level of the stage can be increased is reached. At this time, when all of the decorative symbols are changed to special symbols (for example, flame symbols) almost all at once, the level of the stage is increased. (Suddenly level up)

Next, it reaches the second timing at which the stage level-up fan production can be started. At this time, when a part of the decorative design (for example, the left design) is changed to the special design, the stage level-up flairing effect is started. Incidentally, the stage-level-up-inducing effect also has a pattern in which it is successful after it has been failed. The level-up effect started at the second timing is effectually continuous with the level-up tilting effect at the third timing, which will be described later.

Next, the third timing is reached, at which the stage level-up fan production can be started. Also at this time, when some level of the decorative design (for example, the right design or the left design and the right design) is changed to the special design in the case where the level-up fanning effect in the second timing is executed or not, Stage level up fan production (production to inspire whether or not the middle symbol changes to a special symbol) is started, and stage level up fan production succeeds (the middle symbol also changes to a special symbol and all symbols change to special symbols) Yes, and the level of the stage will improve. As an example of a failure pattern of a series of level up fanning effects from the second timing to the third timing, the left symbol is a special symbol at the second timing, but the right symbol (and the middle symbol) is a special symbol at the third timing. There is a case where it does not change, or the left symbol and the right symbol become special symbols in the middle of the third timing, but the middle symbol does not finally become a special symbol.

Next, the fourth timing at which the level of the stage can be increased is reached. At this time, when all the decorative symbols are changed to special symbols at the same time, the level of the stage is increased. The effect at the fourth timing is slightly different from the level-up method of the second timing and the third timing (an example in which the symbols are sequentially changed to special symbols at the timing when the symbols are stopped and displayed). A mode in which the appearance character of the subject matter that is the motif for the three decorative patterns that have become is performing the effect that the action is performed on the decorative pattern, and the three decorative patterns during fluctuation are changed to the special pattern almost at the same time. Are listed.

Next, the timing of the level up of the stage after the decorative pattern becomes a tempai will be described.

After the decorative design becomes tempai (sometimes referred to as "normal reach"), the fifth timing at which any of a plurality of stage level-up effects may occur is reached.

At the 5th timing, the stage level is raised by the button effect, the stage level is raised after the reach, the stage level is raised by the fanned effect, the stage level is raised after the normal reach loss (the middle pattern is +1 shift), and the normal reach loss (the middle pattern is -1 shift). It is configured so that the stage level up by the special stage level up production of, and the stage level up after the mission reach can occur.

The stage level up by the button effect indicates that the stage level up is confirmed when the button image is displayed on the effect display device SG at the timing, and the stage level is increased regardless of the button operation.

Post-reach stage level-up In the stage level-up by the fanning effect, after the reach-up stage level-up fanning effect is introduced, the post-reach stage level-up fanning effect occurs, and if successful, the stage level increases, In case of failure, the stage level will be maintained.

When the level of the stage after the normal reach loss (the middle symbol is +1 shift) is increased and the middle symbol is lost by the normal reach +1 shift (example: 787), it is determined in advance that the stage level is to be increased. , The stage level is up. In addition, in the normal reach, when the middle symbol is shifted by +1 and is lost, the stage level is not necessarily raised.

When the special reach level is raised after the normal reach loss (the middle pattern is shifted by -1), the stage level is 1 and the middle pattern is lost by -1 in normal reach (example: 767). A special stage level up effect that raises the stage level is generated, and the stage level is raised to stage level 3. It should be noted that the special stage level-up effect is not necessarily performed when the middle pattern is -1 shift and loses at the stage level 1 in the normal reach.

When increasing the stage level after mission reach, the player moves to mission reach after the tenpai, and the stage level increases to level 3 after mission reach. In the mission reach, the lost design, the winning design, the super reach development design, and the stage level 3 transition design rotate like a roulette wheel, and a display corresponding to the stopped design is performed. That is, the stage level is increased to the stage level 3 when the stage level 3 transition pattern is stopped.

In order to be able to recognize the stage level, the character display showing the staying stage is configured to be displayed, for example, in the upper right or upper left of the effect display device SG even after the ten-pie (during the reach effect: during the normal reach, during the super reach). Alternatively, the characters such as “Lv2” and “Lv3” may be displayed when the stage level is increased.

The effects related to the level-up at each of the level-up timings mentioned here are merely examples, and the level-up effects may be executed in different modes at each timing. For example, although the example of the effect using the decorative design is shown in the period of timing 1 to 4 before the reach, the effect without using the decorative design may be executed.

<Flow of stage level up before tempai>
Next, FIG. 86 is an image diagram of the stage level up before the tempai.

At present, the player is staying on the stage A, which is the stage level 1, and there is one hold of the first main game symbol (first special symbol), and the fluctuation of the first main game symbol is stopped. On the display screen of the effect display device SG, one first hold display is displayed, and the first hold sub-display showing the number of hold of the first main game design is displayed as "1" on the right side of the second decorative design. The first decorative design (main decorative design) and the second decorative design (sub decorative design) are stopped and displayed at "861", and the characters "Stage A" are displayed.

Next, the fluctuation is started, the first decorative pattern and the second decorative pattern are displayed in a variable manner (for example, scroll display, rotation display, etc.), the first hold display is erased, and the variation suggestion display is displayed. The first hold sub-display is decremented by 1 to "0". Incidentally, since the user stayed on the stage A, the character display of "stage A" remains as it is.

Next, all the first decorative symbols are changed to flame symbols which are special symbols. (Suddenly level up)

Next, when the first decorative design changed to a flame design, which is a special design, the stage level increased and the stage level 2 became stage AA, so the stage character display was “Lv2: stage AA”. Has become.

Next, the variable display of the first decorative pattern is started again (re-changed).

Next, the left symbol is displayed as "8", and then the left symbol is changed from "8" to the flame symbol. (Second timing)

Next, the right symbol is displayed as "6", and then the right symbol is changed from "6" to the flame symbol. (3rd timing start)

Next, a fueling effect (for example, gradually changing from a thin flame pattern to a dark flame pattern) is performed on whether or not the flame pattern is displayed in the middle pattern.

Next, the middle design is displayed as a flame design, and all the first decorative designs are flame designs. (End of 3rd timing)

Next, when the first decorative symbol was changed to the flame symbol which is a special symbol again, the stage level was increased and the stage level 3 became stage XXX, so the stage character display was “Lv3: stage XXX”. It has become.

Next, the variation display of the first decorative symbol is started again (re-variation), and thereafter, the game proceeds to the variation stop at the stage XXX of the stage level 3. Even if the level is not raised at the first timing, if the level is raised at the second timing and the third timing, the first decorative symbol is changed again, so that the change is changed again. During the period, the stage level may be raised again at the second timing and the third timing (or the fourth timing).

Although the end of the level-up effect is not shown in the figure, if the effect is lost based on the notice effect of the content corresponding to the stage level, or if it is a big hit, the level-up effect is It is configured to be terminated. For example, in stage level 2, it ends when it develops into normal reach or super reach and loses (or big hit), and when it shifts to stage level 3 it loses (or big hit) in super reach. There is an example configured to end. As a modified example, in the variation after the conditions for the final stage are satisfied, when the variation mode having the degree of expectation equal to or higher than the level-up effect that was scheduled to be finished is executed, the stage level is succeeded. It may be configured to display.

<Preliminary lottery>
Next, with reference to FIG. 87, an example of a preliminary drawing lottery method when the stage level is increased will be described.

First, in the gaming machine, whether or not the stage level is increased is configured based on a variation pattern (variation mode) determined by the CPU MC of the main control board M. Here, the case where the variation pattern 30 (Lv1→temporary stop (flame pattern)→Lv2→normal reach→battle reach→hit) is selected will be described.

When the CPU SC of the sub-control board S receives the information (command, etc.) regarding the fluctuation pattern of the determined fluctuation pattern, it executes the advance notice lottery corresponding to the determined fluctuation pattern.

First, the CPUSC of the sub-control board S first performs a lottery to determine whether or not to execute the advance notice to be executed in the stage A, which is the stage level 1. In the stage A, three notices, that is, notice A1, notice A2, and notice A3 are configured to be executable, and a lottery is performed in which it is possible to collectively determine whether or not to execute each notice. For example, ID0 is "notice A1: none (not execute), notice A2: none, notice A3: none", and ID1 is "notice A1: yes (execute), notice A2: none, notice A3: none" , And ID2 is "notice A1: Yes, notice A2: Yes, notice A3: No".

Next, the advance notice pattern that determines the display mode of the advance notice that is decided to be executed is drawn. Here, when ID1 ("Announcement A1: Yes, A Notice A2: None, A Notice A3: None") is selected in the lottery of whether or not to execute the notice of the previous stage A, that is, it is decided to execute the notice A1. Therefore, the advance notice pattern lottery for the advance notice A1 is executed. As the notice pattern, for example, ID0 is pattern 1, ID1 is pattern 2, and ID2 is pattern 3, and here it is assumed that ID1 is selected.

Next, a lottery is performed to determine whether or not to execute the advance notice to be executed at the stage AA which is the stage level 2. In the stage AA, three notices, that is, a notice AA1, a notice AA2, and a notice AA3 are configured to be executable, and a lottery is performed in which it is possible to collectively determine whether or not to execute each notice. For example, ID0 is "notice AA1: none (not executed), notice AA2: none, notice AA3: none", and ID1 is "notice AA1: Yes (execute), notice AA2: None, notice AA3: None" , And ID2 is "notice AA1: Yes, notice AA2: Yes, notice AA3: No".

Next, the advance notice pattern that determines the display mode of the advance notice that is decided to be executed is drawn. Here, when ID2 (“Announcement AA1: Yes, Notice AA2: Yes, Notice AA3: No”) is selected in the lottery for execution of the notice of the previous stage AA, that is, the notice AA1 and the notice AA2 are executed. Since it has been decided, the notice pattern lottery for the notice AA1 and the notice AA2 is executed. As the notice pattern, for example, in each notice, ID0 is pattern 1, ID1 is pattern 2, and ID2 is pattern 3. Here, it is assumed that ID0 is selected for the advance notice AA1 and ID2 is selected for the advance notice AA2.

Next, a lottery is executed to determine whether or not to execute the notice to be executed during the reach. During the reach, three notices, that is, the reach 1, the reach 2, and the reach 3 are executable, and a lottery is performed in which it is possible to collectively determine whether or not to execute each of the advance notices. For example, ID0 is "1: none in reach, 2: none in reach, 3: none in reach", and ID1 is "1: in reach, 2: none in reach, 3: none in reach", ID2 is "1 in reach, 2: in reach, 3: in reach".

Next, the advance notice pattern that determines the display mode of the advance notice that is decided to be executed is drawn. Here, if ID1 (“reach during 1: yes, reach during 2: yes, reach during 3: no”) is selected in the lottery for execution of advance notice during reach, that is, execute during reach 1. Since it has been decided to do so, the advance notice pattern lottery for reach 1 is executed. As the notice pattern, for example, ID0 is pattern 1, ID1 is pattern 2, ID2 is pattern 3, and ID3 is pattern 4. Here, it is assumed that ID2 is selected.

Next, a lottery is executed to determine whether or not to execute a notice to be executed during the super reach (SP) (battle SP, etc.). During the super reach, three notices of SP 1; SP 2; and SP 3 are configured to be executable, and a lottery is performed in which it is possible to collectively determine whether or not to execute the respective announcements. For example, ID0 is "1: none in SP, 2: None in SP, 3: None in SP", and ID1 is "1: in SP, 2: None in SP, 3: None in SP". ID2 is "1: in SP, 2: in SP, 3: in SP".

Next, the advance notice pattern that determines the display mode of the advance notice that is decided to be executed is drawn. Here, when ID2 (“1: in SP, 2: in SP, 3: in SP: none”) is selected in the lottery of whether or not to execute the advance notice in the previous SP, that is, 1 in SP and SP Since it has been decided to execute Medium 2, the advance notice pattern lottery for SP Medium 1 and SP Medium 2 is executed. As the notice pattern, for example, in each notice, ID0 is pattern 1, ID1 is pattern 2, ID2 is pattern 3, and ID3 is pattern 4. Here, it is assumed that ID 3 is selected for SP 1 and ID 3 is selected for SP 2.

Next, to summarize the results of the preliminary lottery,
1. Lottery on whether or not to execute advance notice at stage level 1 (stage A) ⇒ ID1: Advance notice A1 is available 2. Notice pattern of notice A1 ⇒ ID1: Pattern 2
3. 3. Execution possibility of advance notice in stage level 2 (stage AA) ⇒ ID2: Advance notice AA1 exists, advance notice AA2 exists 4. Notice pattern lottery for notice AA1 ⇒ ID0: Pattern 1
Notice AA2 notice pattern lottery ⇒ ID2: Pattern 3
5. Whether or not to execute advance notice during reach ⇒ ID1: 1 during reach 6. Reach 1 advance notice pattern lottery ⇒ ID2: Pattern 3
7. 7. Whether or not to execute advance notice during SP ⇒ ID2: 1 in SP, 2 in SP 8. Advance notice pattern lottery 1 in SP ⇒ ID3: Pattern 4
Advance notice pattern lottery 2 in SP ⇒ ID3: Pattern 4
Has become.

As described above, by associating the possibility of performing the stage level up with the variation pattern, it is possible to execute only the advance notice lottery necessary for the advance stage lottery even in the advance notice lottery. ..

<Example of change of notice lottery>
If the stage level up is not linked to the fluctuation pattern and is decided by lottery (stage level up feasibility lottery, timing lottery, level up number lottery, etc.), it is assumed that each stage level If the content of the notice production displayed when is executed in the above, all the notice lottery is executed for each stage level (from the start of variation to the end of variation), and the timing for raising the level (timing at which the level-up production occurs) is separately The notice effect that is executed when the stage level is raised in the lottery and variable display may be configured to switch the result of the notice lottery according to the stage level after the level is raised.

Specifically, if the player is staying in the stage A at the start of fluctuation, first, the notice execution possibility lottery and the pattern lottery (including the reach and SP) in the stage A in the stage level 1 and the stage AA in the stage level 2 The advance notice lottery and pattern lottery, and the advance notice lottery and pattern lottery of stage XXX in stage level 3 are executed.

Next, a stage level-up lottery is carried out, and in the stage level-up execution feasibility lottery, if execution of the stage level-up is not decided, the decision result of the preliminary execution feasibility lottery and pattern lottery of the stage A which is the stage level 1 If only the execution/execution timing of the stage level-up and the number of level-ups are determined by the stage level-up execution availability lottery, the stage which is the stage level 1 before the stage level-up is performed. After the stage level is raised, the decision result of the advance notice feasibility or pattern lottery of the stage AA of the stage level 2 or the stage XXX of the stage level 3 is used after the stage level is raised. It will be.

<Flow of stage improvement by prefetching performance>
Next, FIG. 88 is an image diagram of stage level up by prefetching effect. For example, when a new hold (third hold) occurs, the CPUMC of the main control board M makes a pre-judgment to obtain a judgment result that the fluctuation pattern number 32 in FIG. The CPUSC of the control board S performs the prefetch execution possibility lottery based on the command indicating that the variation pattern number 32 transmitted from the CPUMC of the main control board M is executed, and the execution of the stage level up by the prefetch effect is determined. This is an example of the flow of effects that can be executed in the case of.

At present, the player is staying on the stage A, which is the stage level 1, and there are three reservations of the first main game symbol (first special symbol), and the fluctuation of the first main game symbol is stopped. On the display screen of the effect display device SG, three first hold displays are displayed, and the first hold sub-display showing the number of hold of the first main game symbol is displayed as "3" on the right side of the second decorative symbol. The first decorative design (main decorative design) and the second decorative design (sub decorative design) are stopped and displayed at "861", and the characters "Stage A" are displayed.

Next, the variation is started, the first decorative symbol and the second decorative symbol are displayed in a variable manner, one first pending display is deleted and the variation suggesting display is displayed, and the first pending sub-display is decremented by one. It has been set to "2". Incidentally, since the user stayed on the stage A, the character display of "stage A" remains as it is.

Next, although a small explosion image is displayed substantially in the center of the effect display device SG, the stage level is not raised when the small explosion image is displayed.

Next, the display of the small explosion image is erased, and the first decorative pattern and the second decorative pattern are stopped at “716”, which is a variable stop. The fluctuation suggestion display is not displayed when the fluctuation is stopped.

Next, the next variation is started, the first decorative pattern and the second decorative symbol are displayed in a variable manner, one first pending display is deleted and the variation suggestive display is displayed, and the first pending sub-display is decremented by one. It has been set to "1". Incidentally, since the user stayed on the stage A, the character display of "stage A" remains as it is.

Next, a small explosion image is displayed substantially at the center of the effect display device SG, and then the small explosion image is changed to a large explosion image.

Next, since the display of the large explosion image is erased and the stage level is raised when the large explosion image is displayed, the character display of "Lv2: Stage AA" is performed, and the first decorative pattern and the second decorative pattern are displayed. The decorative pattern is stopped at "871", which is a fluctuation stop.

Next, the next fluctuation is started, and thereafter, the game progresses until the fluctuation stops at the stage AA of the stage level 2.

In this way, the prefetching effect executed before the change of the prefetching trigger hold (the hold that has been won in the lottery for starting the prefetching effect) is an effect for suggesting that the prefetching trigger hold is a big hit. The fact is that there is almost no expectation of a big hit for the change before the change in the prefetch trigger hold. In this example, although not described in detail, the notice can be displayed even after the pre-reading effect is displayed. However, when the pre-reading effect is displayed, whether or not the variation is a big hit It may be configured not to display a notice for inciting such a situation. For example, when the pre-reading effect displayed before the pre-reading trigger is held is configured to be displayed only when there is a loss variation, when the pre-reading effect is displayed, the variation does not hit the player. By paying attention only to the display mode of No. 3, it is possible to effectively support whether or not there is a change due to the subsequent hold.

Also, in this example, as the variation pattern of the loss in the low probability/low base (normal time), the variation mode a1 of 3 seconds, the variation mode a2 of 5 seconds, and the like, which have a relatively short variation time, are provided. Therefore, the prefetch effect is configured to be displayed immediately after the start of fluctuation.

In the variation of the prefetch effect, at least some of the advance notice lottery tables (the advance notice execution/non-execution lottery table and the pattern lottery table) are different when the stage level is raised and when the stage level is not raised. Becomes

Furthermore, when the look-ahead effect (including the stir-up effect of the stage level up, that is, regardless of the success or failure of the stage level up) is executed, the notice that may occur immediately after the start of the fluctuation, that is, the look-ahead effect and the effect display timing With regard to the notice that can be duplicated, even if it is decided to execute the notice in the notice lottery, it is configured not to execute (cancel), so that the display of the prefetch effect is not disturbed. Good.

In addition, when the prefetch effect is executed, a predetermined lottery table may be used so that the notice of overlapping display is not executed.

In addition, when the prefetch effect is executed, the execution timing of the notice that the display overlaps can be changed, and the notice that the prefetch effect and the display would otherwise be displayed after the display of the prefetch effect is displayed. It may be configured such that the notice effects of both can be displayed.

In this example, in the stage level up in the prefetching effect, the display of the small explosion image and the large explosion image is used without using the decorative pattern, but a configuration using the decorative pattern may be used. For example, the stage level may be increased when the special symbol is displayed.

<Stage level up lottery table for prefetching>
Next, FIG. 89 is a stage level improvement lottery table for prefetching effect.

First, as a precondition shown in this figure, there is a case where the execution of the prefetch effect is decided in the newly entered hold, and the next change is a change related to the hold of "hold 3", First, the change related to the hold of "hold 2", the change related to the hold of "hold 1", and the change of the hold related to "the concerned change" in which the execution of the prefetching effect is finally determined are sequentially changed.

Note that, for example, when execution of the prefetching effect is newly determined for the third pending hold, it is configured such that any one of IDs 4 to 8 in the figure is determined, and the next variation is "hold 2 It is possible to configure such that it is a variation related to the reservation of “”.

The execution possibility lottery of the look-ahead effect is executed when there is no variation pattern of reach or higher in the hold entered first, and until the change of the hold that triggers the look-ahead effect ends. Will be described assuming that a new prefetch effect execution/non-execution lottery is not performed, but if there is a variation pattern of reach or more in the hold that entered first, even if the prefetch effect is already being executed, The pre-reading effect may or may not be drawn. In this case, it is possible to adopt a configuration in which the result of the feasibility lottery and the pattern lottery by the new prefetching effect are overwritten and executed.

In the stage level-up lottery table, the success/failure of the stage level-up until the change of the hold (here, the change=the latest hold) that triggers the start of the look-ahead effect is performed is collectively determined.

For example, when ID1 is selected, first, when the fluctuation related to the hold of "Hold 3" starts, a stirrer effect of stage level up (display of a small explosion image in FIG. 88) is displayed, but failure (=stage The level does not increase, that is, the large explosion image in FIG. 88 is not displayed), and the fluctuation ends. Next, when the fluctuation related to the hold of "holding 2" is started, the stirrer effect of the stage level up is displayed, but it fails and the fluctuation ends. Next, when the change related to the hold of "Hold 1" is started, a stirrer effect of increasing the stage level is displayed, and the success (=the stage level increases, that is, the large explosion image in FIG. 88 is displayed), The stage level rises from level 1 to level 2 and the fluctuation ends. Next, the fluctuation related to the hold of the “corresponding fluctuation” starts at the stage level 2.

Note that, as shown by the variation pattern number 32 in FIG. 87, when the variation is determined to start from Lv2 by the CPUMC of the main control board M and the CPUSC of the sub control board S. In the above, the CPU SC of the sub-control board S may be configured to be able to select ID1 and ID5 as a stage level-up (prefetch) pattern.

In this way, as shown in FIG. 33, FIG. 86, FIG. 88, etc., in this gaming machine, it is suggested whether or not a big hit is caused by increasing the stage level within one fluctuation based on the fluctuation pattern. Pattern and the effect of increasing the stage level by a plurality of fluctuations by the fluctuation related to the subsequent holding is omitted (for example, when the stage level is raised by the pre-reading effect and the LV2 fluctuation starts, the pre-reading is started. It is not necessary to display an effect in which the stage level is raised from level 1 to level 2 in the target variation), and a pattern that suggests whether or not to be a big hit is provided.

In this gaming machine, there is a possibility that a variation pattern (example: variation mode A4) associated with a stage level increase by prefetching effect is selected even when there is no hold.

In this case, since the look-ahead effect cannot be executed, the pattern based on ID7 or ID8 is configured to be selected, and the stage level up, which cannot be executed as the look-ahead effect, is executed at the start of the fluctuation (immediately after the fluctuation starts). You can deal with it. Here, in the prefetch lottery for the hold that occurs under the condition of no hold, an example in which the stage level is raised immediately after the start of fluctuation (the stage level is suddenly increased) is configured to win the prefetch lottery result ID However, if the stage level has not been raised by the start of the change, the stage level is raised not in the look-ahead lottery but in the advance notice lottery at the start of the change that will cause the change of the change mode A4. It may be configured to determine the effect contents to be performed.

As described above, the variation in which the look-ahead effect (success or failure of stage level up) is executed is a change pattern that does not reach, and a notice other than the look-ahead effect (for example, normal Notice) is not executed. With such a configuration, the player pays attention to the look-ahead effect, and the look-ahead effect can be felt as an effect with a high expectation for a big hit.
<<<Reach production>>>
Next, FIG. 90 is a timing chart of the destruction effect, which is a reach effect.

The extermination effect is an effect during the reach that can occur after the tempai (reach), and determines the development effect 1 that develops after this. It should be noted in advance that the development effect 1 (battle effect) does not necessarily develop after the destruction effect, and the development effect 2 (battle effect) does not necessarily develop after the development effect 1.

First, when the destruction effect is started, the character can be selected. In the destruction effect, the effect mode is configured to be different depending on the selected character.

<Timing chart when character A is selected>
When the character A is selected, the button effect is generated up to three times. There are three patterns of press pattern, single press, long press, and continuous hit, and continuous hits are easy to be selected when the expectation of a big hit is high. Is configured for use. In addition, long press does not destroy the one button effect period when this long press is selected, but indicates that it is a chance (it is highly possible to destroy many enemies) at the next button operation. It is configured (specifically, when a subsequent button effect occurs, an image simulating a button that is an operation promotion image of the effect button is displayed in a chance-up mode such as red, and more enemies are destroyed. That can be mentioned). At the end of the extermination effect, there is performed a development agitation button effect in which the development effect 1 develops when it succeeds and the variation ends when it fails. Furthermore, after the development performance 1, the development performance 2 can be executed.
<Timing chart when character B is selected>
When the character B is selected, 6 button effects are generated. The pressing pattern is only one-time pressing, and is configured to suggest the jackpot expectation degree according to the effect mode displayed. At the end of the destruction effect, as in the case of selecting the character A, the development-inspiring button effect is performed in which the success is developed into the development effect, and when the character A is unsuccessful, the variation ends. Furthermore, after the development performance 1, the development performance 2 can be executed.

As described above, in the destruction effect, the character A and the character B are configured to be selectable, and the effect time of the character A and the effect time of the character B are the same effect time. It should be noted that different effect modes are executed by configuring the effect time for one button effect (single press) when the character A is selected and the effect time for two button effects when the character B is selected to be approximately the same time. It is possible.

<Flow of destruction effect when character A is selected>
Next, the flow of the destruction effect when the character A is selected will be described with reference to FIG. 91.

First, the display screen is changing at stage A, and the template is established at “8”.

Next, a character selection screen for developing the destruction effect and selecting the character A or the character B is displayed. On the character selection screen, the characters "Please select a character" are displayed, the choices "A" and "B", and the cross key SB-2 for executing the selection are displayed. The character selection is configured to be confirmed when a predetermined time (for example, 3 seconds) has elapsed, and the currently selected option is highlighted during the selection. There is.

Next, the selected character (here, the character A) is displayed, which suggests that the effect display is to destroy the enemy. Further, here, the reach pattern "8" is displayed at the upper part of the screen, the decorative pattern numbers are displayed at the bottom of the screen from 1 to 8, and the number of destroyed enemies is displayed (here, " 0/8”) is being performed. The numbers that are decorative symbols at the bottom of the screen are the final stop symbols other than the left symbol and the right symbol that are in the reach state, and represent the candidate symbols as the stop symbol of the decorative symbol in the changing middle symbol column. ..

Next, the enemy character (one of the enemy characters 1 to 18 in the destruction effect) is displayed, and a button image indicating that the button can be pressed to destroy the enemy character is displayed.

Next, when the enemy character is destroyed, "x" is displayed on the enemy character, the number of destructions is displayed as "1/8", and "4" which is a decorative pattern that can be selected is "x". Is displayed, and it is a display indicating that “4” is not selected as the lost design of the final stop design displayed in the first decorative design.

Next, the character A is displayed before the second button press.

Next, an enemy character different from the first time is displayed, a button image is displayed, and the button can be pressed the second time.

Next, when the enemy character is destroyed, "x" is displayed on the enemy character, and the number of destructions is displayed as "2/8", and "5" which is a decorative pattern that can be selected is "x". Is displayed, and the display shows that "5" is not selected as the lost symbol.

Next, the character A is displayed before the third button press.

Next, an enemy character different from the first and second times is displayed, a button image is displayed, and the button can be pressed the third time.

Next, when the enemy character is destroyed, "x" is displayed on the enemy character, and the number of destructions is displayed as "3/8", and "2" which is a symbol that can be selected has "x". It is displayed and shows that "2" is not selected as a lost symbol.

Next, a button presentation is performed to suggest whether or not the production will be developed into development production 1 (battle production), and a character display and a button image of "If the button is successful, the battle production is developed!" are displayed. ing.

Next, the development fan button production for suggesting whether or not to develop into the development production 1 (battle production) is successful, and the production movable object YK is moving in front of the production display device SG.

Next, it has been developed into development production 1 (battle production).

In this way, in the destruction effect when the character A is selected, the lost symbol is destroyed (including the display of “×”) every time the enemy character is destroyed, and it is shown that the lost symbol is not selected. It is configured so that the possibility of being selected can be recognized visually.

In addition, the button pressing pattern in the destruction effect when the character A is selected is
(1) Single press → Single press → Single press (2) Single press → Long press → Single press (3) Single press → Continuous hit (4) Long press → Single press → Single press (5) Long press → Continuous hit Is configured.

In addition, the symbol destruction in the destruction effect when the character A is selected (display of "x" in the candidate display of the final stop decorative symbol at the bottom of the screen) is
(1) Single press: No pattern destruction, 1 pattern destruction, 2 symbol destruction, 3 symbol destruction (2) Long press: Next symbol destruction 3, Next symbol destruction 4, Next symbol destruction 5 6, next symbol destruction 6 (3) In case of continuous hitting: It is configured to be selected from 3 symbol destruction, 4 symbol destruction, 5 symbol destruction, 6 symbol destruction.

<Flow of destruction production when character B is selected>
Next, the flow of the destruction effect when the character B is selected will be described with reference to FIG.

First, the display screen is changing at stage A, and the template is established at “8”.

Next, the character selection screen for selecting the character A or the character B is displayed, which has been developed into the destruction effect. On the character selection screen, the characters "Please select a character" are displayed, the choices "A" and "B", and the cross key SB-2 for executing the selection are displayed. The character selection is configured to be confirmed when a predetermined time (for example, 3 seconds) has passed, and the currently selected option is highlighted during the selection. There is.

Next, the selected character (here, the character B) is displayed, which suggests that the effect display is to destroy the enemy. Further, here, the reach pattern "8" is displayed at the upper part of the screen, the decorative pattern numbers are displayed at the bottom of the screen from 1 to 8, and the number of destroyed enemies is displayed (here, " 0/8”) is being performed.

Next, the enemy character is displayed, a button image for destroying the enemy character is displayed, and a target mark is displayed on the design "6" to be destroyed. When the character B is selected, the plurality of button images become one button when destroying the enemy character, and the number of the plurality of button images gathered suggests the degree of expectation of destroying the design. Here, an effect pattern in which two button images are gathered is displayed, and when the two button images are moved so as to overlap the lower center of the screen, a button image display mode indicating that the operation of the effect button is effective is displayed. It is configured as follows.

Next, in the case where the enemy character could not be destroyed, the enemy character is displayed without being destroyed, and the number of destructions displayed remains "0/8". However, the pattern "6" to be destroyed has cracks.

Next, the character B is displayed before the second button depression.

Next, the same enemy character as the first time is displayed again, an effect pattern in which two button images are gathered is displayed, and the button can be pressed the second time. It should be noted that the target mark is displayed again on the cracked "6".

Next, when the enemy character is destroyed, "x" is displayed on the enemy character, the number of destructions is displayed as "1/8", and "x" is displayed on the symbol "6" on which the target mark is displayed. It is displayed and shows that "6" is not selected as the lost symbol.

Next, the character B is displayed before the button is pressed for the third time.

Next, an enemy character different from the first and second times is displayed, an effect pattern in which four button images are gathered is displayed, a target mark is displayed on the design "3" to be destroyed, and the button is pressed the third time. Is possible.

Next, when the enemy character is destroyed, "x" is displayed on the enemy character, and further, "x" is displayed on the symbol "3" on which the target mark is displayed, and further four button images are gathered. Since the effect pattern is a chance pattern, "x" is also displayed in "4", indicating that "3" and "4" are not selected as the lost symbols, and the number of destructions is displayed. It is "3/8". In this example, only one target mark is displayed, and the "x" display is also displayed on the design in which the target mark is not displayed, so that the player has an additional chance at the timing of the effect result display. Although it is configured to display that the target mark is displayed, the target mark is displayed first for all the designs that will not be selected as the loss design first due to the display pattern of the button image, the type of the enemy character, etc. May be

After that, the production is performed up to the sixth time, and similarly to when the character A is selected, a button production for finally indicating whether or not to develop into the development production 1 (battle production) is performed. If it succeeds, the battle display will develop!" and the button image is displayed.

Next, the development fan button production for suggesting whether or not the development production 1 (battle production) is developed fails, and the production movable object YK does not move on the front surface of the production display device SG, and the variation stops. Has become.

In addition, the button pressing pattern in the destruction effect when the character B is selected is only one-time pressing.

Further, the symbol destruction in the destruction effect when the character B is selected is configured to correspond to the number of button images,
(1) 2 button images: nothing, crack, 1 destruction, multiple destruction (2) 4 button images: 1 destruction, multiple destruction (3) 8 button images: multiple destruction selected It

<Supplement to Common Specifications for Character A and Character B>

The enemy characters (1 to 18) appearing during the destruction effect are associated with the enemy character and the expected degree of the symbol destruction number. For example, the expected degree of the symbol destruction number is the enemy character 1<the enemy character 7<the enemy. It can be configured to be the character 12. Furthermore, the repeated hits and the eight button images, which are high-expectancy patterns of symbol destruction, are configured to easily occur in the order of enemy character 1<enemy character 7<enemy character 12.

It is preferable that the enemy characters (1 to 18) are divided into groups according to the degree of expectation of the number of destroyed symbols, and the low expectation group: enemy characters 1 to 6, the middle expectation group: enemy character 7 ~ 12, high-expectancy group: enemy characters 12-18, etc. can be configured.

If the button is not pressed during the destruction effect, apparently the enemy character is not destroyed and the design is not destroyed. In addition, when the button is not pressed, a structure is displayed such as "?/?", "1/?", "?/8" so that the player cannot recognize the number of symbols destroyed. May be

When a long press pattern is selected during the destruction effect and the effect button is pressed for a long time, the button image changes to a chance button image (one size larger, etc.) and the chance button image is semitransparent until the next button press timing. Is continuously displayed and indicates that the next button press is an opportunity. On the other hand, when the effect button is not pressed for a long time, the button image is erased and the semitransparent chance button image is not displayed.

In the continuous hitting pattern during the destruction effect, a plurality of enemy characters (the same character may be used, or different characters may be collectively used) are displayed to be destroyed, and it is easy to recognize that it is a chance.

The development to the development effect 1 is that if the number of destroyed symbols in the destruction effect is three, the development to the battle effect A with the enemy character A and the jackpot rate (expectation level) is 1/5 (8 Of the decorative patterns, three decorative patterns are destroyed and not selected), and if the number of destroyed patterns in the destruction effect is four, it develops into a battle effect B with the enemy character B and becomes a big hit. The ratio is 1/4, and if the number of destroyed symbols in the extermination effect is 5 or more, it develops into the battle effect C with the enemy character C, and the ratio of a big hit is 1/3, and in the extermination effect. If the number of symbols destroyed is 6, the battle effect D with the enemy character D is developed, and the ratio of a big hit is 1/2.

It is preferable that the success probability of the development fan button effect is configured to increase as the number of destroyed symbols increases (the greater the number of destroyed symbols, the more advanced development production 1, that is, the battle production with high expectation. However, if the development performance 1 is not developed, the expectations of the player will be disappointing and the player's willingness to play will decline. Further, when the number of destroyed symbols is three or less, a pattern that succeeds in the development fan button effect may be provided, and when the number of destroyed symbols is three or less, the process may be shifted to the battle effect A.

In addition, if the number of symbols destroyed is three or more, it may be configured to succeed in the development fan button effect and shift to the battle effect.

Furthermore, the battle production D with the enemy character D occurs as development production 1 when transitioning to destruction production→development production 1 and transition to destruction production→development production 1 (≠ battle production D)→development production 2 It is configured so that it can occur in two ways when it occurs as the development effect 2 in the case of performing.

Specifically, as described above, if the number of symbols destroyed in the destruction production is 6 or more, the battle production D is developed, and if the number of symbols destroyed in the production production is 5 or less, the battle productions A to C are obtained. Develop. The effect is configured so that the symbols can be destroyed even while the battle effects A to C are being executed. For example, the symbol is destroyed in the SP 1 or the like determined in the lottery of the preliminary announcement during the super reach (SP) of FIG. 87. It is configured to determine the presence or absence.

In this case, three more symbols are destroyed during the execution of battle production A, two more symbols are destroyed during the execution of battle production B, and one more symbol is destroyed during the execution of battle production C. Since the total number of symbols destroyed is 6, the condition to develop into the battle production D as the development production 2 after the battle production of the development production 1 being executed is satisfied, and the battle production D is made after the battle production being executed. Develop. In addition, even if one (or two) symbols are destroyed by the destruction of the symbols during the battle effects A and B, the battle effects B and battle with a higher jackpot expectation than the battle effects being executed. There is no development to the production C, and when the total of 6 symbols is destroyed, the battle production D is developed.

Therefore, the display of “N/M” (N=number of symbols destroyed, M=total number of target symbols) indicating the number of symbols destroyed may be continued during the execution of the battle effects A to C. However, the number of symbols destroyed may be hidden during the execution of the battle effect. In addition, when the display of "N/M" is configured to be continued during the execution of the battle effects A to C, the display is hidden when the last symbol destruction timing during the execution of the battle effects A to C has elapsed. can do.

Further, as a modified example, with respect to a specific battle effect (for example, the battle effect D that has the highest degree of expectation and may develop even after the transition to another battle effect) among the battle effects A to D, a big hit variation may occur. As a condition to be executed (winning in the effect lottery), when the big hit is a big hit symbol α2, it is set as a condition. (High probability after a big hit/big hit that shifts to a high base)”, and is configured to increase the attention of the player to the destruction of the symbols during the destruction effect or the battle effect. Good.

<<<Chance>>>
Next, a chance eye that is a special stop combination, which is one of the prefetch effects, will be described.

The color of the decorative pattern in this gaming machine is "1: green" "2: blue" "3: red" "4: blue" "5: green" "6: blue" "7: red" "8: It is configured to be “blue”, and like other notice expectations, the jackpot expectations indicated by the decorative pattern are configured to increase in the order of blue<green<red. For example, the green pattern reach has a higher jackpot expectation than the blue symbol reach, and the red symbol reach has a higher jackpot expectation than the green symbol reach. Further, similarly in the chance eye described here, the jackpot expectation degree is increased in the order of blue symbol chance eye<green symbol chance eye<red symbol chance.

The chance eye in the gaming machine may be a state in which three decorative patterns of the same color are not arranged, and two identical decorative patterns may be arranged side by side. For example, if it is “223”, it is configured as a blue symbol chance eye of “2”, if it is “655”, it is a green symbol chance eye of “5”, and if it is “533”, it is configured as a red symbol chance eye of “3”. ..

First, as described with reference to FIG. 70, the chance item is executed when the lottery result (the opportunity item is won) including “Opportunity item: Yes” is included in the lottery by the look-ahead lottery table.

When the chance number is won in the lottery based on the look-ahead lottery table, one of the execution patterns is determined with reference to the chance item scenario determination table in FIG.

Next, the chance eye scenario pattern will be described with reference to FIG.

The chance eye scenario pattern that can be determined when a new game ball enters the fourth hold is:
(1) ID0...3 Before change: left blue → 2 before change: left blue → 1 before change: left blue * "Left blue" constitutes a blue symbol chance eye with left symbol and middle symbol (2) ID1・・・3 before change: left blue→2 before change: left blue→1 before change: right blue * “Right blue” constitutes the blue symbol chance eye with the middle symbol and the right symbol (3) ID2...・Before 3 changes: Left blue → Before 2 changes: Left green → Before 1 changes: Right green (4) ID3... Before 3 changes: Left blue → Before 2 changes: Left green → Before 1 changes: Right red (5 ) ID4・・・3 before change: left blue → before 2 change: left green → 1 before change: promoted right red * "promoted right red" is likely to be displayed once or after a green symbol chance is displayed , Red pattern chance eye is composed of middle pattern and right pattern (6) ID5...3 Before change: left blue → 2 before change: promotion left green → 1 before change: promotion right red * "Promotion left green" , The blue pattern chance eye is about to be displayed or once it is displayed, then the green symbol chance eye is composed of the left symbol and the middle symbol (7) ID6...3 before change: left green → 2 before change: left Green→1 before change: left green (8) ID7・・・3 before change: left green→2 Before change: left green→1 before change: left red (9) ID8・・・3 before change: left green→2 Before change: left red→1 before change: right red (10) ID9...3 Before change: right red→2 before change: right red→1 before change: right red

The chance eye scenario pattern that can be determined when a new game ball enters the third hold,
(1) ID0...2 before change: left blue→1 before change: left blue (2) ID1...2 before change: left blue→1 before change: right green (3) ID2...2 before change : Left blue→Before 1 change: Promotion Right green (4) ID3・・・2 Before change: Left green→1 Before change: Left green (5) ID4・・・2 Before change: Left green→1 Before change: Right Red (6) ID5... 2 before change: left green→1 before change: promotion right red (7) ID6...2 before change: right red→1 before change: right red.

The chance eye scenario pattern that can be determined when a new game ball enters the second hold,
(1) ID0...1 before change: left blue (2) ID1...1 before change: left green (3) ID2...1 before change: promotion right green (4) ID3...1 before change : Right red (5) ID4... 1 before change: Promotion Right red.

It should be noted that ID0 is easily selected when the jackpot expectation is low, difficult to be selected when the jackpot expectation is high, and ID9 is easily selected when the jackpot expectation is high, and is selected when the jackpot expectation is low. It is configured to be difficult, that is, the larger the ID is, the easier it is to select when the jackpot expectation is high.

Incidentally, when the chance pattern is determined and the stop symbol is determined in the decorative symbol display content determination processing in step 5700, it is determined which stop symbol is the chance symbol. At this time, it is preferable that the stop symbol is determined so as not to reach. Further, the two stop symbols forming the chance eye may be the same symbol or different symbols (for example, symbols of the same color).

Next, the flow of the production of the chance eye will be described with reference to FIG. 94. The decorative symbols are "1" for a green symbol, "6" for a blue symbol, "7" for a red symbol, and "8" for a blue symbol.

First, in the state where the first main game symbol (first special symbol) is reserved, the variation is stopped with the decorative symbol "861".

Next, the fluctuation is started, and the first decorative pattern and the second decorative pattern are displayed in a variable manner (for example, scroll display, rotation display, etc.), and one first hold display is erased to display the variation suggestion display. Then, the first reserved sub-display is decremented by 1 to become "3".

Next, immediately before the fluctuation stop, the first decorative symbol is temporarily stopped and displayed at "667", which is the blue symbol chance.

Next, the fluctuation is stopped, and the first decorative symbol and the second decorative symbol are fixedly stopped at “667”.

Next, the next change is started, the first decorative symbol and the second decorative symbol are displayed in a variable display, one of the first hold displays is erased, the change suggestion display is displayed, and the first hold sub-display is displayed. One is subtracted to become "2".

Next, immediately before the fluctuation stop, the first decorative symbol is temporarily stopped and displayed at "118", which is the green symbol chance.

Next, the variation is stopped, and the first decorative symbol and the second decorative symbol are fixedly stopped at “118”.

Next, the next change is started, the first decorative symbol and the second decorative symbol are displayed in a variable display, one of the first hold displays is erased, the change suggestion display is displayed, and the first hold sub-display is displayed. One is subtracted to become "1".

Next, "1" is temporarily stopped and displayed on the left symbol, and then "7" is temporarily stopped and displayed on the right symbol.

Next, a display that the middle symbol "1" moves from the top to the bottom of the liquid crystal screen is displayed, and a display that fuels whether or not the "1" stops and becomes the green symbol chance is displayed. ..

Next, the middle symbol "1" is temporarily stopped and displayed, which is in the shape of a green symbol chance eye. Here, instead of temporarily displaying "1" of the middle symbol, a display may be displayed to fuel whether or not "1" is stopped.

Next, the symbol row of the middle symbols is changed and displayed again.

Next, immediately before the fluctuation stop, the first decorative symbol is temporarily stopped and displayed at "177", which is a red symbol chance. That is, in this variation, the red symbol chance eye is shown instead of the green symbol chance eye.

In order to be able to accurately recognize the chance eye for each change, for example, when the chance eye in the change is displayed, an effect is displayed (for example, blue pattern chance eye ⇒ blue effect, green pattern chance eye ⇒ Green effect, red pattern chance eyes ⇒ red effect) may be configured. With such a configuration, here, the green effect is not displayed in the display of the green chance eye before the re-change, but the red effect is displayed in the display of the red chance eye after the re-change.

Next, the fluctuation is stopped, and the first decorative symbol and the second decorative symbol are fixedly stopped at “177”.

Then, next, the fluctuation of the hold that has triggered the start of the chance opportunity (=winning the execution possibility lottery of the chance opportunity) has started.

<<Supplementary Opportunity>>
<Display pattern>
For example, when the left symbol is "4" (blue symbol) and the right symbol is "5" (green symbol), the middle symbol is slowly scrolled and displayed as "5" (green symbol). When it becomes, the symbol “5” is displayed and becomes the green symbol chance eye, so that the symbol which can be the chance eye of low expectation (“4” here) and the symbol which can be the chance eye of high expectation (here: It is preferable to determine the decorative pattern so that “5”) is a pattern having a number as close as possible.

By making the determination in this way, the time required to display the high-chance opportunity is shortened. For example, the time required for scrolling after "4" to display "5" (4→5) requires scrolling time for one symbol, and scrolling after "4" to "1" The time required to display (4→5→6→7→8→1 or 4→3→2→1) requires scrolling time for five symbols or three symbols.

In addition, it is preferable not only to execute the pattern for advancing the symbol but also to determine the decorative symbol so that the symbols on the left and right become numbers as close as possible even when the pattern for returning is executed. Is.

Further, in this gaming machine, when the blue pattern (“2”, “4”, “6”, “8”) chances are displayed, and the green symbols (“1”, “5”) chances are displayed Is configured such that a green pattern close to the blue pattern is selected. For example, if the blue design is "2", the green design is "1", if the blue design is "4", the green design is "5", and if the blue design is "6", the green design is "5", When the blue symbol is "8", the green symbol is "1".

With this configuration, it is possible to display the chance increase in a short time without spending more time than necessary when increasing the chance, and to reduce the stress felt by the player being able to show the opportunity increase for a long time. Can be reduced.

Further, as a modified example, when the chance eyes are continuously displayed over a plurality of fluctuations, at least one of the symbols stopped and displayed on the left symbol and the right symbol is the expectation degree indicated by the last chance symbol symbol. It should be configured to have the chance eye composition pattern of the same degree of expectation (for example, if it was the blue pattern chance eye last time, stop and display the blue pattern on the left symbol or the right symbol), and the left and right symbols in order. When it is stopped and displayed, the chance eye composition pattern having the same degree of expectation as the previous degree is always displayed first (for example, the stop display order of the decorative design should be the order of the left design, the right design, and the middle design). For example, if the left design is to be a blue design, or if the right design can be stopped and displayed before the left design as a pattern of the stop display order of the decorative design, the blue design is stopped as the blue design on the right design first. It may be configured to stop).

With such a configuration, when the chance eye is displayed in the previous change, the decorative pattern that is first stopped and displayed is a chance eye composition pattern that can have a higher degree of expectation than the previous chance eye, Opportunity with a higher degree of expectation than the previous change is displayed in a situation where the expectation is high that the second stop display symbol and the third stop display symbol are lower than the chance eye composition pattern that was first stopped and displayed. It is possible to prevent the expectation degree chance composition pattern from being stopped and displayed, and the expectation being displayed as if it decays within one change. In this modified example, in the first variation of the chance eye effect, the left eye and the right eye are configured such that the stop order of the chance eye constituent symbols is not provided, and for example, it is not known whether or not the chance eye is stopped and displayed. There is no possibility of the stop display of the chance eye because the symbol that is first stopped and displayed in the changing eye is "3: red design" (the design that can be displayed as the chance eye composition design above the red design as the second stop design) I try to prevent it).

<Display pattern>
In FIG. 94, the pattern in which the middle symbol is scrolled again to be the red symbol chance eye is described, but the pattern is not limited to the pattern in which only the middle symbol is scrolled again in this way, and the left symbol or the right symbol which is temporarily stopped first. A pattern may be provided in which any one of the symbols is also scrolled again to display the chance. For example, the chance item may be displayed as "4↓6" ⇒ "4(4)6" (4 is a temporary stop display) ⇒ "4↓↓" ⇒ "455".

Also, a promotion failure pattern may be provided. For example, if the pattern is "3 before change: left blue → 2 before change: left blue → 1 before change: promotion failure left blue", before 3 changes and before 2 changes, left pattern and middle as usual The blue symbol chance eye by the symbol is displayed, and before one change, "4 ↓ 5" ⇒ "4(4)5" ⇒ "4 ↓ 5" ⇒ "445" so that it is promoted from the blue symbol chance eye Although it looks as if to do, it is not actually promoted and the blue pattern chance eye is displayed.

Further, in the promotion failure pattern, it is preferable to stop at a symbol close to the blue symbol so as not to be mistaken for promotion to the green symbol. For example, "445" (left blue pattern chance eye) ⇒ (next change) "4↓5" ⇒ "435". At this time, as a player, is it "445" and the blue symbol chance eye continues, or is it "455" and is promoted to the green symbol chance, or is the chance eye ended? We are paying attention to which one. The decorative pattern is scrolling at a low speed, and I expect greatly that the next "5" will stop (promote) when "4" passes (does not stop), but here "5" If it passes, the player will be very discouraged. Therefore, when the chance eye does not continue, by stopping the symbol (here, "3") displayed in front of the symbol (here, blue symbol "4") with a lower expectation of chance chance, It is preferable that the player is configured not to have useless expectations, and only if the chance of opportunity continues or is promoted, it is expected to be the same as the last time or to be promoted.

In addition, a pattern in which the display of the chance chance is started and the display of the chance chance is completed (before the hold held in the execution possibility lottery lottery starts changing) or the display of the chance chance is terminated once A pattern to be restored may be provided.

(Pattern in which the display of the chance eye ends halfway)
For example, as a chance eye scenario pattern that can be determined when a new game ball enters the fourth hold, a pattern of “3 before change: left blue→before 2 change: left blue→1 before change: none” May be provided.

Specifically, as shown in FIG. 95, stop at "861" ⇒ 3 before change: stop at "667" (blue symbol chance) ⇒ before 2 change: stop at "667" (blue symbol chance) ⇒ Before 1 change: "6 ↓ 7 → 6 (6) 7 (in the middle symbol "6", a blue symbol chance eyes stop swaying) → 6 ↓ 7 → 617" (no chance eyes). It should be noted that this pattern is likely to be selected when the big hit expectation is low.

In addition, if there is no chance before one change, by configuring the blue symbol to be selected as the left symbol or the right symbol, it becomes possible to fuel whether or not the blue symbol chance will continue. ..

(Pattern that reappears after the display of the first chance ends)
For example, as a chance eye scenario pattern that can be determined when a new game ball enters the fourth hold, a pattern of “3 before change: left blue→2 before change: none→1 before change: left blue” May be provided.

Specifically, as shown in FIG. 96, "861" ⇒ 3 before change: "667" (blue symbol chance eye) ⇒ 2 before change: none ⇒ 1 before change: "667" (blue symbol chance eye) Become. Since this pattern is finally the blue symbol chance, it is easy to be selected when the big hit expectation degree is low.

(Display of the second decorative pattern at the opportunity display timing)
When the first decorative symbol (main decorative symbol) is fixedly stopped at the chance, the second decorative symbol (sub decorative symbol) is also fixedly stopped at the chance. In addition, since the second decorative design continues to scroll while changing, a chance is temporarily displayed in the first decorative design by executing a pattern such as "promotion left green" (in this case, "left blue" Even if it is displayed), the second decorative symbol does not perform the display corresponding to the chance eye that is once displayed as the first decorative symbol.

(Sound effect corresponding to the stop display of the chance eye)
When the chance eye is stopped and displayed as the first decorative pattern, a special stop sound may be output to indicate that it is the chance eye. The blue symbol chance eye, the green symbol chance eye, and the red symbol chance eye may have different special stop sounds, or the blue symbol chance eye and the green symbol chance eye, which are relatively low expectations, have the same special stop sound, A different special stop sound may be set for the red symbol chance eye, which has a relatively high degree of expectation.

<Prohibition processing>
(In case of shortened fluctuation loss)
When a new hold occurs after the trigger hold after the start of the chance eye effect as the prefetch effect, the change display from 3 changes before to 1 change before the change for trigger hold is shortened. (Variation mode a1, 3 seconds), and in this case, it is not possible to secure the production time to be promoted, so promotion green (promotion left green, promotion right green), promotion red (promotion left red, promotion) Right red) is configured not to run.

For example, when ID5 is selected in the hold 4, the promotion left green is executed 2 changes before. However, if the shortened variation loss (variation mode a1, 3 seconds) is selected as the variation before the two variations, there is no time for displaying the blue symbol chance eye once and then promoting it to the green symbol chance. , It is configured to change from the beginning to a pattern for displaying left green (stopping the green pattern on the left symbol and the middle symbol) instead of promoting it at the start of fluctuation.

(Chance eyes and timer production)
FIG. 97 is a modification of the block diagram of the prefetch lottery table of FIG. 70.

In this figure, "timer effect" is provided as a type of prefetch effect, and when the timer effect is displayed once, it is displayed in the change of the hold (prefetch trigger hold) for which execution of the timer effect is decided in the prefetch lottery table. Will continue to be displayed until is finished. For example, when execution of the timer effect is determined in the hold 4, the character display of "waiting for timer" is displayed from the start of the next change, and the character of "waiting for timer" is displayed at a predetermined timing in the change of the prefetch trigger hold. The display changes to, for example, "60:00" (60 seconds), the countdown starts from "60:00", and when "00:00" is reached, the display of the timer effect is erased and the timer effect ends.

Like this timer effect, there is a look-ahead effect that is continuously displayed until the change of the read-ahead trigger is held, and the execution of the timer effect such as the above-mentioned "pattern of the display of the chance eye ending halfway" and the like. When combined, there is a concern that the player's interest in the timer effect may be significantly reduced due to the pattern in which the display of the chance eyes ends in the middle of the chance eyes.

Therefore, in the pre-fetch lottery execution possibility lottery in the pre-reading lottery table, a pattern that the display of the chance eyes is not executed in the middle is set to "No chance eye gaze", and when the timer effect and the chance eyes are simultaneously won, It is possible to configure so that the pattern for ending the display of the chance is not executed.

In addition, when the "no chance chance gaze" is not provided, the chance opportunity scenario determination table may be changed according to whether or not the timer effect is won. Specifically, when the timer effect is won, a chance-eye scenario determination table that does not have a pattern in which the display of the chance eyes ends halfway is used, but when the timer effect is not won, the opportunity-eye scenario determination table is used. Then, a chance-eye scenario determination table having a pattern in which the display of the chance eyes ends is used.

(Stage level up and chance)
In the stage level up in the prefetching effect, as described above, the special pattern may be used as the decorative pattern. However, since the decorative pattern is used even at the chance, the prefetch lottery table may be configured so that both cannot be executed at the same time.

It is also possible to provide a chance item scenario determination table so that a special symbol that triggers the stage level up can be displayed in the chance item.

For example, in the case of reservation 4 in FIG. 93, a pattern of “3 before change: left blue→2 before change: left green→1 before change: promotion special symbol” is provided, and before the first change, a green symbol chance to a red symbol It can be configured so that a special symbol is displayed while appearing to be promoted to the chance.

In addition, in the fluctuation in which it is decided to execute the “promotion special symbol”, when the shortened fluctuation loss (variation time of 3 seconds in this example) is selected as the fluctuation pattern, the effect that appears to be promoted is executed. The special symbol can be changed to a pattern in which the special symbol is stopped and displayed without the need for the special symbol to be displayed.

<Example of change of chance>
(Effective line)
The gaming machine has been described as a 1-line machine having 1 effective line, but in the case of a 5-line machine having 5 effective lines, the same symbol may be displayed on the liquid crystal display screen with a shift. In this case, as the chance eye, the big hit expectation degree can be configured to be different depending on the display shape of the same symbol.

Specifically, the chances are as shown in FIGS. 98(A) to (D), and the jackpot expectation degree is configured to be D=C<B<A. Here, when the symbols forming the chance eye are displayed in the middle, the expectation of the jackpot of the trigger hold is the highest, and the case where two symbols are lined up is the second highest, and the three symbols are scattered. The case is the lowest. Even in the case of such a configuration, the promotion effect can be executed before the symbol row of the middle row, which is the final stop symbol row, stops. For example, by scrolling one or two symbols in the middle row to the left from the situation in which it is likely to be stopped and displayed in the mode of FIG. 98(C) or the temporarily stopped state, it is a display mode of higher expectation ( A) or (B), or a case of changing to the mode of (A) by returning one symbol in the middle row from the mode of FIG. 98(B) to the right. ..

In addition, you may apply the structure described as the 1st line machine of this game machine, when the two symbols are lined up, it is a chance.

In addition, the chance eye may be treated as a chance eye by the display mode of the main stop of the decorative symbol that is stopped and displayed together with the stop display of the special symbol, or may be decorated multiple times during one variable display of the special symbol. The temporary stop display mode at the timing of the temporary stop display of the decorative symbol may be treated as a chance item when the re-variation effect for performing the variable display of the symbols is executed.

<<<Specification change example>>>
In the present embodiment, the so-called ST machine (probability variation number cut) in which the probability variation ends at 10,000 times has been described, but it is also possible to apply to a gaming machine in which the probability variation continues until the “next big hit”.

M main control board A 1st main game-related electric member, A10, A10-2 1st main game start opening A11s, A11s-2 1st main game start entrance ball detection device A20 1st main game symbol display device A21g 1st Main game symbol display section, A21h 1st main game symbol hold display section B 2nd main game-related electric member, B10 2nd main game starting opening B11s 2nd main game starting opening ball detection device B20 2nd main game symbol displaying apparatus , B21g second main game symbol display section B21h second main game symbol hold display section C first and second main game shared related electrical members, C10 first big winning opening C11s first big winning opening winning detection device, C11d first Big winning mouth electric prize C20 2nd big winning mouth, C21s 2nd big winning mouth winning detection device C21d 2nd big winning mouth electric auditors FS sorting device, FB sorting member HD-1 first non-electric winning product, HD-2 2nd non-electric role E10 auxiliary game electric role, E10s auxiliary game electric role entering detector N1 1st opening entrance, N1 2nd opening entrance H auxiliary game related electric member, H10 auxiliary Game starting mouth H11s auxiliary game starting entrance ball detection device, H20 auxiliary game symbol display device H21g auxiliary game symbol display part, H21h auxiliary game symbol hold display part S sub-control board, SM effect display control means (sub-main control board)
SS effect display means (sub-sub control unit)
SG effect display device, SG10 display area SG11 decorative pattern display area, SG12 first hold display portion SG13 second hold display portion SG14 the variation suggestion display portion SB sub-input button, SBs sub-input button input detection device SB-2 cross key KH Prize ball payout control board, KE prize ball payout device

Claims (1)

A starting opening that allows game balls to enter,
An identification information display unit capable of displaying identification information,
A main game unit that controls the progress of the game,
A production display unit that can display productions,
It is provided with a sub-game section that controls the effect display on the effect display section,
The main game department is
Random number acquisition means for acquiring a random number based on the ball entering the starting opening,
When a random number is acquired by the random number acquisition means, a random number temporary storage means for temporarily storing the acquired random number as a hold until the acceptance/rejection determination permission condition is satisfied,
When the acceptance/rejection determination permission condition for a certain hold is satisfied, the acceptance/rejection determination is executed based on the random number related to the certain hold, and the stop display mode of the identification information and the variable display mode of the identification information are determined based on the result of the acceptance/rejection determination. A game content determination means,
Identification information display control means for controlling the identification information to be stopped and displayed after the identification information is variably displayed on the identification information display part according to the determination by the game content determination means,
Special game control means capable of executing a special game in a state advantageous to the player after the result of the determination on the basis of the random number is a win and the identification information is stopped and displayed,
And a game information transmitting means for transmitting to the sub-game unit the game information necessary for effect display executed on the sub-game unit side,
The sub-game department
Game information receiving means for receiving the game information transmitted from the main game section side,
Based on the game information received by the game information receiving means, effect display content control means for controlling the effect display content displayed on the effect display unit,
After the production symbols are variably displayed on the production display unit, the production symbol display control means for controlling to display the final display mode of the production symbols on the production display unit,
With multiple types of development effects that are different in the possibility that the result of the win/fail judgment is a win,
Of a plurality of types of development production, has a development production transition suggestion production for suggesting which development production to transition to,
In the development effect transition suggestion effect, a plurality of final display mode candidate symbols that can be a part of the final display mode are displayed, and one or more final display mode candidate symbols cannot be selected as a part of the final display mode depending on a predetermined condition. Is displayed in a non-candidate display mode indicating that
The larger the number of final display mode candidate symbols that have become non-candidate display modes in the development effect transition suggestion pattern, the more likely it is that the result of the win/fail judgment is a win Suru Pachinko game machine.